Complex integrals
This article completes the topic of indefinite integrals, and it includes integrals that I consider quite difficult. The lesson was created at the repeated request of visitors who expressed their wish that more difficult examples be analyzed on the site.
It is assumed that the reader of this text is well prepared and knows how to apply the basic techniques of integration. Dummies and people who are not very confident in integrals should refer to the very first lesson - Indefinite integral. Solution examples where you can learn the topic almost from scratch. More experienced students can get acquainted with the techniques and methods of integration, which have not yet been encountered in my articles.
What integrals will be considered?
First, we consider integrals with roots, for the solution of which we successively use variable substitution And integration by parts. That is, in one example, two methods are combined at once. And even more.
Then we will get acquainted with an interesting and original method of reducing the integral to itself. Not so few integrals are solved in this way.
The third number of the program will be integrals of complex fractions, which flew past the cash register in previous articles.
Fourthly, additional integrals from trigonometric functions will be analyzed. In particular, there are methods that avoid the time-consuming universal trigonometric substitution.
(2) In the integrand, we divide the numerator by the denominator term by term.
(3) We use the property of linearity of the indefinite integral. In the last integral, immediately bring the function under the sign of the differential.
(4) We take the remaining integrals. Note that you can use brackets in the logarithm and not the modulus, because .
(5) We carry out the reverse substitution, expressing from the direct substitution "te":
Masochistic students can differentiate the answer and get the original integrand, as I just did. No, no, I did the check in the right sense =)
As you can see, in the course of the solution, even more than two solution methods had to be used, so to deal with such integrals, you need confident integration skills and not the least experience.
In practice, of course, the square root is more common, here are three examples for independent solution:
Example 2
Find indefinite integral
Example 3
Find the indefinite integral
Example 4
Find the indefinite integral
These examples are of the same type, so the complete solution at the end of the article will be only for Example 2, in Examples 3-4 - one answer. Which replacement to use at the beginning of decisions, I think, is obvious. Why did I choose the same type of examples? Often found in their roles. More often, perhaps, just something like 
.
But not always, when under the arc tangent, sine, cosine, exponent, and other functions there is a root of linear function, it is necessary to apply several methods at once. In a number of cases, it is possible to “get off easy”, that is, immediately after the replacement, a simple integral is obtained, which is taken elementarily. The easiest of the tasks proposed above is Example 4, in which, after the replacement, a relatively simple integral is obtained.
The method of reducing the integral to itself
Clever and beautiful method. Let's take a look at the classics of the genre:
Example 5
Find the indefinite integral
There is a square binomial under the root, and when trying to integrate this example, the teapot can suffer for hours. Such an integral is taken by parts and reduces to itself. In principle, it is not difficult. If you know how.
Let us denote the considered integral by a Latin letter and start the solution: 
Integrating by parts: 
(1) We prepare the integrand for term-by-term division.
(2) We divide the integrand term by term. Perhaps not everyone understands, I will write in more detail:
(3) We use the property of linearity of the indefinite integral.
(4) We take the last integral ("long" logarithm).
Now let's look at the very beginning of the solution: 
And for the ending: 
What happened? As a result of our manipulations, the integral has reduced to itself!
Equate the beginning and end: 
We transfer to the left side with a change of sign: 
And we demolish the deuce to the right side. As a result: 
The constant, strictly speaking, should have been added earlier, but I added it at the end. I strongly recommend reading what is the severity here:
Note:
More strictly, the final stage of the solution looks like this:
Thus:
The constant can be re-named with . Why can you rename? Because it still takes any values, and in this sense there is no difference between constants and.
As a result:
A similar trick with constant renaming is widely used in differential equations. And there I will be strict. And here such liberties are allowed by me only in order not to confuse you with unnecessary things and focus on the very method of integration.
Example 6
Find the indefinite integral
Another typical integral for independent solution. Complete Solution and the answer at the end of the lesson. The difference with the answer of the previous example will be!
If under square root located square trinomial, then the solution in any case reduces to two analyzed examples.
For example, consider the integral 
. All you need to do is in advance select a full square:
.
Next, a linear replacement is carried out, which manages "without any consequences":
, resulting in an integral . Something familiar, right?
Or this example, with a square binomial:
Selecting a full square:
And, after a linear replacement , we get the integral , which is also solved by the already considered algorithm.
Consider two more typical examples of how to reduce an integral to itself:
is the integral of the exponent multiplied by the sine;
is the integral of the exponent multiplied by the cosine.
In the listed integrals by parts, you will have to integrate twice already:
Example 7
Find the indefinite integral
The integrand is the exponent multiplied by the sine.
We integrate by parts twice and reduce the integral to itself: 
As a result of double integration by parts, the integral is reduced to itself. Equate the beginning and end of the solution:
We transfer to the left side with a change of sign and express our integral: 
Ready. Along the way, it is desirable to comb the right side, i.e. take the exponent out of brackets, and place the sine and cosine in brackets in a “beautiful” order.
Now let's go back to the beginning of the example, or rather, to integration by parts: 
For we have designated the exhibitor. The question arises, it is the exponent that should always be denoted by ? Not necessary. In fact, in the considered integral fundamentally doesn't matter, what to denote for, one could go the other way: 
Why is this possible? Because the exponent turns into itself (when differentiating and integrating), the sine and cosine mutually turn into each other (again, both when differentiating and integrating).
That is, the trigonometric function can be denoted as well. But, in the considered example, this is less rational, since fractions will appear. If you wish, you can try to solve this example in the second way, the answers must be the same.
Example 8
Find the indefinite integral
This is a do-it-yourself example. Before deciding, think about what is more profitable in this case to designate for, exponential or trigonometric function? Full solution and answer at the end of the lesson.
And, of course, don't forget that most of the answers in this lesson are fairly easy to check by differentiation!
The examples were considered not the most difficult. In practice, integrals are more common, where the constant is both in the exponent and in the argument of the trigonometric function, for example: . Many people will have to get confused in such an integral, and I myself often get confused. The fact is that in the solution there is a high probability of the appearance of fractions, and it is very easy to lose something due to inattention. In addition, there is a high probability of error in signs, note that there is a minus sign in the exponent, and this introduces additional difficulty.
At the final stage, it often turns out something like this:
Even at the end of the solution, you should be extremely careful and correctly deal with fractions: 
Integration of complex fractions
We are slowly approaching the equator of the lesson and begin to consider integrals of fractions. Again, not all of them are super complex, just for one reason or another, the examples were a little “off topic” in other articles.
Continuing the theme of roots
Example 9
Find the indefinite integral
In the denominator under the root there is a square trinomial plus outside the root "appendage" in the form of "x". An integral of this form is solved using a standard substitution.
We decide: 
The replacement here is simple: 
Looking at life after replacement: 
(1) After substitution, we reduce the terms under the root to a common denominator.
(2) We take it out from under the root.
(3) We reduce the numerator and denominator by . At the same time, under the root, I rearranged the terms in a convenient order. With some experience, steps (1), (2) can be skipped by performing the commented actions orally.
(4) The resulting integral, as you remember from the lesson Integration of some fractions, is solved extraction method full square
. Select a full square.
(5) By integration, we obtain an ordinary "long" logarithm.
(6) We carry out the reverse replacement. If initially , then back: .
(7) The final action is aimed at hairdressing the result: under the root, we again bring the terms to a common denominator and take them out from under the root.
Example 10
Find the indefinite integral 
This is a do-it-yourself example. Here, a constant is added to the lone x, and the replacement is almost the same: 
The only thing that needs to be done additionally is to express the "x" from the replacement: 
Full solution and answer at the end of the lesson.
Sometimes in such an integral there may be a square binomial under the root, this does not change the way the solution is solved, it will even be even simpler. Feel the difference:
Example 11
Find the indefinite integral
Example 12
Find the indefinite integral
Brief solutions and answers at the end of the lesson. It should be noted that Example 11 is exactly binomial integral, the solution method of which was considered in the lesson Integrals of irrational functions.
Integral of an indecomposable polynomial of the 2nd degree to the degree
(polynomial in denominator)
More rare, but, nevertheless, meeting in practical examples type of integral.
Example 13
Find the indefinite integral
But back to the example with the lucky number 13 ( honestly, did not guess). This integral is also from the category of those with which you can pretty much suffer if you don’t know how to solve.
The solution starts with an artificial transformation: 
I think everyone already understands how to divide the numerator by the denominator term by term.
The resulting integral is taken in parts: 
For an integral of the form ( – natural number) derived recurrent downgrading formula:
, Where 
is an integral of a lower degree.
Let us verify the validity of this formula for the solved integral .
In this case: , , we use the formula: 
As you can see, the answers are the same.
Example 14
Find the indefinite integral
This is a do-it-yourself example. The sample solution uses the above formula twice in succession.
If under the degree is indecomposable square trinomial, then the solution is reduced to a binomial by extracting the full square, for example:
What if there is an additional polynomial in the numerator? In this case, the method of indeterminate coefficients is used, and the integrand is expanded into a sum of fractions. But in my practice of such an example never met, so I skipped this case in the article Integrals of a fractional-rational function, I'll skip it now. If such an integral still occurs, see the textbook - everything is simple there. I do not consider it expedient to include material (even simple), the probability of meeting with which tends to zero.
Integration of complex trigonometric functions
The adjective "difficult" for most examples is again largely conditional. Let's start with tangents and cotangents in high degrees. From the point of view of the methods used to solve the tangent and cotangent are almost the same, so I will talk more about the tangent, meaning that the demonstrated method of solving the integral is also valid for the cotangent.
In the above lesson, we looked at universal trigonometric substitution to solve a certain type of integrals from trigonometric functions. The disadvantage of the universal trigonometric substitution is that its application often leads to cumbersome integrals with difficult calculations. And in some cases, the universal trigonometric substitution can be avoided!
Consider another canonical example, the integral of unity divided by the sine:
Example 17
Find the indefinite integral
Here you can use the universal trigonometric substitution and get the answer, but there is a more rational way. I will provide a complete solution with comments for each step:
(1) Use trigonometric formula sine of a double angle.
(2) We carry out an artificial transformation: In the denominator we divide and multiply by .
(3) According to the well-known formula in the denominator, we turn the fraction into a tangent.
(4) We bring the function under the sign of the differential.
(5) We take the integral.
A couple of simple examples to solve on your own:
Example 18
Find the indefinite integral
Hint: The very first step is to use the reduction formula 
and carefully carry out actions similar to the previous example.
Example 19
Find the indefinite integral
Well, this is a very simple example.
Complete solutions and answers at the end of the lesson.
I think now no one will have problems with integrals: 
and so on.
What is the idea behind the method? The idea is to use transformations, trigonometric formulas to organize only tangents and the derivative of the tangent in the integrand. That is, we are talking about replacing: 
. In Examples 17-19, we actually used this replacement, but the integrals were so simple that it was done with an equivalent action - bringing the function under the differential sign.
Similar reasoning, as I have already mentioned, can be carried out for the cotangent.
There is also a formal prerequisite for applying the above substitution:
The sum of the powers of cosine and sine is a negative integer EVEN number, For example:
for an integral, an integer negative EVEN number.
! Note : if the integrand contains ONLY sine or ONLY cosine, then the integral is taken even with a negative odd degree (the simplest cases are in Examples No. 17, 18).
Consider a couple of more meaningful tasks for this rule:
Example 20
Find the indefinite integral
The sum of the degrees of sine and cosine: 2 - 6 \u003d -4 - a negative integer EVEN number, which means that the integral can be reduced to tangents and its derivative: 
(1) Let's transform the denominator.
(2) According to the well-known formula, we obtain .
(3) Let's transform the denominator.
(4) We use the formula 
.
(5) We bring the function under the differential sign.
(6) We carry out the replacement. More experienced students may not carry out the replacement, but still it is better to replace the tangent with one letter - there is less risk of confusion.
Example 21
Find the indefinite integral
This is a do-it-yourself example.
Hold on, the championship rounds begin =)
Often in the integrand there is a "hodgepodge":
Example 22
Find the indefinite integral 
This integral initially contains a tangent, which immediately suggests an already familiar thought:
I will leave the artificial transformation at the very beginning and the rest of the steps without comment, since everything has already been said above.
A couple of creative examples for an independent solution:
Example 23
Find the indefinite integral 
Example 24
Find the indefinite integral 
Yes, in them, of course, you can lower the degrees of the sine, cosine, use the universal trigonometric substitution, but the solution will be much more efficient and shorter if it is drawn through tangents. Full solution and answers at the end of the lesson
Integrals of logarithms
Integration by parts. Solution examples
Solution.
Eg.
Calculate integral:
Applying the properties of the integral (linearity), ᴛ.ᴇ. , reduce to a table integral, we get that
Hello again. Today in the lesson we will learn how to integrate by parts. The method of integration by parts is ϶ᴛᴏ one of the cornerstones of the integral calculation. On a test, an exam, a student is almost always offered to solve integrals of the following types: the simplest integral (see articleIndefinite integral. Solution examples ) or an integral to change the variable (see articleVariable change method in indefinite integral ) or the integral just on method of integration by parts.
As always, on hand should be: Table of integrals And Derivative table. If you still don’t have them, then please visit the pantry of my site: Mathematical formulas and tables. I will not get tired of repeating - it is better to print everything. I will try to present all the material in a consistent, simple and accessible way; there are no particular difficulties in integrating by parts.
What problem does integration by parts solve? The method of integration by parts solves very important task, it allows you to integrate some functions that are not in the table, work functions, and in some cases - and private. As we remember, there is no convenient formula: . But there is this: - the formula for integration by parts in person. I know, I know, you are the only one - with her we will work the whole lesson (it’s already easier).
And immediately the list in the studio. Integrals of the following types are taken by parts:
1) , - logarithm, logarithm multiplied by some polynomial.
2) , is an exponential function multiplied by some polynomial. This also includes integrals like - an exponential function multiplied by a polynomial, but in practice it is 97 percent, a pretty letter ʼʼеʼʼ flaunts under the integral. ... the article turns out to be something lyrical, oh yes ... spring has come.
3) , are trigonometric functions multiplied by some polynomial.
4) , are inverse trigonometric functions (ʼʼarchesʼʼ), ʼʼarchesʼʼ, multiplied by some polynomial.
Also, some fractions are taken in parts, we will also consider the corresponding examples in detail.
Example 1
Find the indefinite integral.
Classic. From time to time, this integral can be found in tables, but it is undesirable to use a ready-made answer, since the teacher has beriberi in the spring and he will scold a lot. Because the integral under consideration is by no means tabular - it is taken in parts. We decide:
We interrupt the solution for intermediate explanations.
We use the formula for integration by parts:
Integrals of logarithms - concept and types. Classification and features of the category "Integrals of logarithms" 2017, 2018.
Table of antiderivatives ("integrals"). Table of integrals. Tabular not definite integrals. (Simple integrals and integrals with a parameter). Formulas for integration by parts. Newton-Leibniz formula.
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Table of antiderivatives ("integrals"). Tabular indefinite integrals. (Simple integrals and integrals with a parameter). |
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Power function integral. |
Power function integral. |
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An integral that reduces to an integral of a power function if x is driven under the sign of the differential. |
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The exponential integral, where a is a constant number. |
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Integral of a complex exponential function. |
The integral of the exponential function. |
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An integral equal to the natural logarithm. |
Integral: "Long logarithm". |
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Integral: "Long logarithm". |
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Integral: "High logarithm". |
The integral, where x in the numerator is brought under the sign of the differential (the constant under the sign can be both added and subtracted), as a result, is similar to the integral equal to the natural logarithm. |
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Integral: "High logarithm". |
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Cosine integral. |
Sine integral. |
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An integral equal to the tangent. |
An integral equal to the cotangent. |
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Integral equal to both arcsine and arcsine |
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An integral equal to both the inverse sine and the inverse cosine. |
An integral equal to both the arc tangent and the arc cotangent. |
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The integral is equal to the cosecant. |
Integral equal to secant. |
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An integral equal to the arcsecant. |
An integral equal to the arc cosecant. |
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An integral equal to the arcsecant. |
An integral equal to the arcsecant. |
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An integral equal to the hyperbolic sine. |
An integral equal to the hyperbolic cosine. |
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An integral equal to the hyperbolic sine, where sinhx is the hyperbolic sine in English. |
An integral equal to the hyperbolic cosine, where sinhx is the hyperbolic sine in the English version. |
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An integral equal to the hyperbolic tangent. |
An integral equal to the hyperbolic cotangent. |
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An integral equal to the hyperbolic secant. |
An integral equal to the hyperbolic cosecant. |
Formulas for integration by parts. Integration rules.
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Formulas for integration by parts. Newton-Leibniz formula. Integration rules. |
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Integration of a product (function) by a constant: |
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Integration of the sum of functions: |
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indefinite integrals: |
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Integration by parts formula definite integrals: |
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Newton-Leibniz formula definite integrals: |
Where F(a),F(b) are the values of the antiderivatives at the points b and a, respectively. |
Derivative table. Table derivatives. Derivative of the product. Derivative of private. Derivative complex function.
If x is an independent variable, then:
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Derivative table. Table derivatives. "table derivative" - yes, unfortunately, that's how they are searched on the Internet |
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Power function derivative |
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Derivative of the exponent |
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Derivative of exponential function |
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Derivative of a logarithmic function |
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Derivative of the natural logarithm of a function |
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Cosecant derivative |
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Derivative of inverse tangent |
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Derivative of arc cosecant |
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Derivative of a compound exponential function
Derivative of the natural logarithm
Sine derivative
cosine derivative
Secant derivative
Derivative of arcsine
Arc cosine derivative
Derivative of arcsine
Arc cosine derivative
Tangent derivative
Cotangent derivative
Arc tangent derivative
Derivative of inverse tangent
Arc tangent derivative
Arcsecant derivative
Derivative of arc cosecant
Arcsecant derivative
Derivative of the hyperbolic sine
Derivative of the hyperbolic sine in the English version
Hyperbolic cosine derivative
The derivative of the hyperbolic cosine in the English version
Derivative of the hyperbolic tangent
Derivative of the hyperbolic cotangent
Derivative of hyperbolic secant
Derivative of the hyperbolic cosecant|
Differentiation rules. Derivative of the product. Derivative of private. Derivative of a complex function. |
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Derivative of a product (function) by a constant: |
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Derivative of the sum (functions): |
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Derivative of the product (of functions): |
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The derivative of the quotient (of functions): |
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Derivative of a complex function: |
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Properties of logarithms. Basic formulas of logarithms. Decimal (lg) and natural logarithms (ln).
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Basic logarithmic identity |
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Let us show how any function of the form a b can be made exponential. Since a function of the form e x is called exponential, then |
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Any function of the form a b can be represented as a power of ten |
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Natural logarithm ln (logarithm base e = 2.718281828459045…) ln(e)=1; log(1)=0
Taylor series. Expansion of a function in a Taylor series.
It turns out that most practically encountered mathematical functions can be represented with any accuracy in the vicinity of a certain point in the form of power series containing the powers of the variable in ascending order. For example, in the vicinity of the point x=1:
When using rows called taylor rows, mixed functions containing, say, algebraic, trigonometric, and exponential functions can be expressed as purely algebraic functions. With the help of series, differentiation and integration can often be quickly carried out.
The Taylor series in the vicinity of the point a has the following forms:
1)
, where f(x) is a function that has derivatives of all orders at x=a. R n - the remainder term in the Taylor series is determined by the expression 
2)
k-th coefficient (at x k) of the series is determined by the formula
3) A special case of the Taylor series is the Maclaurin series (=McLaren) (the decomposition takes place around the point a=0)
for a=0 
the members of the series are determined by the formula
Conditions for the application of Taylor series.
1. In order for the function f(x) to be expanded in a Taylor series on the interval (-R;R), it is necessary and sufficient that the remainder term in the Taylor formula (Maclaurin (=McLaren)) for this function tends to zero at k →∞ on the specified interval (-R;R).
2. It is necessary that there are derivatives for this function at the point in the vicinity of which we are going to build a Taylor series.
Properties of Taylor series.
If f is an analytic function, then its Taylor series at any point a of the domain of f converges to f in some neighborhood of a.
There are infinitely differentiable functions whose Taylor series converges but differs from the function in any neighborhood of a. For example:
Taylor series are used in the approximation (approximation - scientific method, which consists in replacing some objects with others, in one sense or another close to the original, but simpler) functions by polynomials. In particular, linearization ((from linearis - linear), one of the methods of approximate representation of closed nonlinear systems, in which the study of a nonlinear system is replaced by an analysis of a linear system, in a sense equivalent to the original one.) of equations occurs by expanding into a Taylor series and cutting off all the terms above first order.
Thus, almost any function can be represented as a polynomial with a given accuracy.
Examples of some common expansions of power functions in Maclaurin series (=McLaren,Taylor in the vicinity of point 0) and Taylor in the vicinity of point 1. The first terms of expansions of the main functions in Taylor and MacLaren series.
Examples of some common expansions of power functions in Maclaurin series (= MacLaren, Taylor in the vicinity of the point 0)
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Examples of some common Taylor series expansions around point 1
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Integration by parts. Solution examples
Hello again. Today in the lesson we will learn how to integrate by parts. The method of integration by parts is one of the cornerstones of integral calculus. At the test, exam, the student is almost always offered to solve integrals of the following types: the simplest integral (see article) or an integral to change the variable (see article) or the integral just on method of integration by parts.
As always, on hand should be: Table of integrals And Derivative table. If you still do not have them, then please visit the storeroom of my site: Mathematical formulas and tables. I will not get tired of repeating - it is better to print everything. I will try to present all the material in a consistent, simple and accessible way; there are no particular difficulties in integrating by parts.
What problem does integration by parts solve? The method of integration by parts solves a very important problem, it allows you to integrate some functions that are not in the table, work functions, and in some cases - and private. As we remember, there is no convenient formula: 
. But there is this one: 
is the formula for integration by parts in person. I know, I know, you are the only one - with her we will work the whole lesson (it’s already easier).
And immediately the list in the studio. Integrals of the following types are taken by parts:
1) , 
, - logarithm, logarithm multiplied by some polynomial.
2) ,
is an exponential function multiplied by some polynomial. This also includes integrals like - an exponential function multiplied by a polynomial, but in practice it is 97 percent, a pretty letter “e” flaunts under the integral. ... the article turns out to be something lyrical, oh yes ... spring has come.
3) , 
, are trigonometric functions multiplied by some polynomial.
4) , - inverse trigonometric functions (“arches”), “arches”, multiplied by some polynomial.
Also, some fractions are taken in parts, we will also consider the corresponding examples in detail.
Integrals of logarithms
Example 1
Classic. From time to time, this integral can be found in tables, but it is undesirable to use a ready-made answer, since the teacher has beriberi in the spring and he will scold a lot. Because the integral under consideration is by no means tabular - it is taken in parts. We decide:
We interrupt the solution for intermediate explanations.
We use the formula for integration by parts: 
The formula is applied from left to right
We look at the left side:. Obviously, in our example (and in all the others that we will consider), something needs to be denoted by , and something by .
In integrals of the type under consideration, we always denote the logarithm.
Technically, the design of the solution is implemented as follows, we write in the column:
That is, for we denoted the logarithm, and for - the remaining part integrand.
Next step: find the differential:
The differential is almost the same as the derivative, we have already discussed how to find it in previous lessons.
Now we find the function . In order to find the function it is necessary to integrate right side lower equality :
Now we open our solution and construct the right side of the formula: .
By the way, here is an example of a final solution with small notes:
The only moment in the product, I immediately rearranged and, since it is customary to write the multiplier before the logarithm.
As you can see, applying the integration-by-parts formula essentially reduced our solution to two simple integrals.
Please note that in some cases right after application of the formula, a simplification is necessarily carried out under the remaining integral - in the example under consideration, we reduced the integrand by "x".
Let's do a check. To do this, you need to take the derivative of the answer:
The original integrand is obtained, which means that the integral is solved correctly.
During the verification, we used the product differentiation rule: 
. And this is no coincidence.
Integration by parts formula 
and formula 
These are two mutually inverse rules.
Example 2
Find the indefinite integral.
The integrand is the product of the logarithm and the polynomial.
We decide.
I will once again describe in detail the procedure for applying the rule, in the future the examples will be made out more briefly, and if you have any difficulties in solving it yourself, you need to go back to the first two examples of the lesson.
As already mentioned, for it is necessary to designate the logarithm (the fact that it is in a degree does not matter). We denote the remaining part integrand.
We write in a column:
First we find the differential:
Here we use the rule of differentiation of a complex function 
. It is no coincidence that at the very first lesson of the topic Indefinite integral. Solution examples I focused on the fact that in order to master the integrals, you need to "get your hand" on the derivatives. Derivatives will have to face more than once.
Now we find the function , for this we integrate right side lower equality :
For integration, we applied the simplest tabular formula 
Now you are ready to apply the formula 
. We open it with an "asterisk" and "design" the solution in accordance with the right side:
Under the integral, we again have a polynomial on the logarithm! Therefore, the solution is interrupted again and the rule of integration by parts is applied a second time. Do not forget that for in similar situations the logarithm is always denoted.
It would be nice if at this point you were able to find the simplest integrals and derivatives orally.
(1) Do not get confused in the signs! Very often a minus is lost here, also note that the minus applies to all bracket 
, and these brackets need to be opened correctly.
(2) Expand the brackets. We simplify the last integral.
(3) We take the last integral.
(4) “Combing” the answer.
The need to apply the rule of integration by parts twice (or even thrice) is not uncommon.
And now a couple of examples for an independent solution:
Example 3
Find the indefinite integral.
This example is solved by the change of variable method (or subsuming under the differential sign)! And why not - you can try to take it in parts, you get a funny thing.
Example 4
Find the indefinite integral.
But this integral is integrated by parts (the promised fraction).
These are examples for self-solving, solutions and answers at the end of the lesson.
It seems that in examples 3,4 the integrands are similar, but the solution methods are different! This is precisely the main difficulty in mastering integrals - if you choose the wrong method for solving the integral, then you can fiddle with it for hours, like with a real puzzle. Therefore, the more you solve various integrals, the better, the easier the test and the exam will be. In addition, in the second year there will be differential equations, and without experience in solving integrals and derivatives there is nothing to do there.
By logarithms, perhaps more than enough. For a snack, I can also remember that tech students call female breasts logarithms =). By the way, it is useful to know by heart the graphics of the main elementary functions: sine, cosine, arc tangent, exponential, polynomials of the third, fourth degree, etc. No, of course, a condom on a globe
I will not pull, but now you will remember a lot from the section Graphs and functions =).
Integrals of the exponent multiplied by the polynomial
General rule:
Example 5
Find the indefinite integral.
Using a familiar algorithm, we integrate by parts:
If you have any difficulties with the integral, then you should return to the article Variable change method in indefinite integral.
The only other thing to do is to "comb" the answer:
But if your calculation technique is not very good, then leave the most profitable option as an answer. 
or even 
That is, the example is considered solved when the last integral is taken. It won’t be a mistake, it’s another matter that the teacher may ask to simplify the answer.
Example 6
Find the indefinite integral.
This is a do-it-yourself example. This integral is integrated twice by parts. Special attention you should pay attention to the signs - it is easy to get confused in them, we also remember that - a complex function.
There is not much more to say about the exhibitor. I can only add that the exponential and the natural logarithm are mutually inverse functions, this is me on the topic of entertaining graphs of higher mathematics =) Stop-stop, don't worry, the lecturer is sober.
Integrals of trigonometric functions multiplied by a polynomial
General rule: always stands for the polynomial
Example 7
Find the indefinite integral.
Integrating by parts:
Hmmm... and nothing to comment on.
Example 8
Find the indefinite integral 
This is an example for a do-it-yourself solution
Example 9
Find the indefinite integral
Another example with a fraction. As in the two previous examples, a polynomial is denoted by.
Integrating by parts: 
If you have any difficulties or misunderstanding with finding the integral, then I recommend attending the lesson Integrals of trigonometric functions.
Example 10
Find the indefinite integral 
This is a do-it-yourself example.
Hint: before using the integration by parts method, you should apply some trigonometric formula that turns the product of two trigonometric functions into one function. The formula can also be used in the course of applying the method of integration by parts, to whom it is more convenient.
That, perhaps, is all in this paragraph. For some reason, I recalled a line from the anthem of the Physics and Mathematics Department “And the sine graph wave after wave runs along the abscissa axis” ....
Integrals of inverse trigonometric functions.
Integrals of inverse trigonometric functions multiplied by a polynomial
General rule: always stands for the inverse trigonometric function.
I remind you that the inverse trigonometric functions include arcsine, arccosine, arctangent and arccotangent. For the sake of brevity, I will refer to them as "arches"
