Formula for finding the difference of an arithmetic progression. How to find the sum of an arithmetic progression: formulas and an example of their use
Sum of an arithmetic progression.
The sum of an arithmetic progression is a simple thing. Both in meaning and in formula. But there are all sorts of tasks on this topic. From basic to quite solid.
First, let's understand the meaning and formula of the amount. And then we'll decide. For your own pleasure.) The meaning of the amount is as simple as a moo. To find the sum of an arithmetic progression, you just need to carefully add all its terms. If these terms are few, you can add without any formulas. But if there is a lot, or a lot... addition is annoying.) In this case, the formula comes to the rescue.
The formula for the amount is simple:
Let's figure out what kind of letters are included in the formula. This will clear things up a lot.
S n - the sum of an arithmetic progression. Addition result everyone members, with first By last. It is important. They add up exactly All members in a row, without skipping or skipping. And, precisely, starting from first. In problems like finding the sum of the third and eighth terms, or the sum of the fifth to twentieth terms, direct application of the formula will disappoint.)
a 1 - first member of the progression. Everything is clear here, it's simple first row number.
a n- last member of the progression. The last number of the series. Not a very familiar name, but when applied to the amount, it’s very suitable. Then you will see for yourself.
n - number of the last member. It is important to understand that in the formula this number coincides with the number of added terms.
Let's define the concept last member a n. Tricky question: which member will be the last one if given endless arithmetic progression?)
To answer confidently, you need to understand the elementary meaning of arithmetic progression and... read the task carefully!)
In the task of finding the sum of an arithmetic progression, the last term always appears (directly or indirectly), which should be limited. Otherwise, a final, specific amount simply doesn't exist. For the solution, it does not matter whether the progression is given: finite or infinite. It doesn’t matter how it is given: a series of numbers, or a formula for the nth term.
The most important thing is to understand that the formula works from the first term of the progression to the term with number n. Actually, the full name of the formula looks like this: the sum of the first n terms of an arithmetic progression. The number of these very first members, i.e. n, is determined solely by the task. In a task, all this valuable information is often encrypted, yes... But never mind, in the examples below we reveal these secrets.)
Examples of tasks on the sum of an arithmetic progression.
First of all, useful information:
The main difficulty in tasks involving the sum of an arithmetic progression lies in the correct determination of the elements of the formula.
The task writers encrypt these very elements with boundless imagination.) The main thing here is not to be afraid. Understanding the essence of the elements, it is enough to simply decipher them. Let's look at a few examples in detail. Let's start with a task based on a real GIA.
1. The arithmetic progression is given by the condition: a n = 2n-3.5. Find the sum of its first 10 terms.
Good job. Easy.) To determine the amount using the formula, what do we need to know? First member a 1, last term a n, yes the number of the last member n.
Where can I get the last member's number? n? Yes, right there, on condition! It says: find the sum first 10 members. Well, what number will it be with? last, tenth member?) You won’t believe it, his number is tenth!) Therefore, instead of a n we will substitute into the formula a 10, and instead n- ten. I repeat, the number of the last member coincides with the number of members.
It remains to determine a 1 And a 10. This is easily calculated using the formula for the nth term, which is given in the problem statement. Don't know how to do this? Attend the previous lesson, without this there is no way.
a 1= 2 1 - 3.5 = -1.5
a 10=2·10 - 3.5 =16.5
S n = S 10.
We have found out the meaning of all elements of the formula for the sum of an arithmetic progression. All that remains is to substitute them and count:
That's it. Answer: 75.
Another task based on the GIA. A little more complicated:
2. Given an arithmetic progression (a n), the difference of which is 3.7; a 1 =2.3. Find the sum of its first 15 terms.
We immediately write the sum formula:
This formula allows us to find the value of any term by its number. We look for a simple substitution:
a 15 = 2.3 + (15-1) 3.7 = 54.1
It remains to substitute all the elements into the formula for the sum of an arithmetic progression and calculate the answer:
Answer: 423.
By the way, if in the sum formula instead of a n We simply substitute the formula for the nth term and get:
Let us present similar ones and obtain a new formula for the sum of terms of an arithmetic progression:
 |
As you can see, the nth term is not required here a n. In some problems this formula helps a lot, yes... You can remember this formula. Or you can simply display it at the right time, like here. After all, you always need to remember the formula for the sum and the formula for the nth term.)
Now the task in the form of a short encryption):
3. Find the sum of all positive two-digit numbers that are multiples of three.
Wow! Neither your first member, nor your last, nor progression at all... How to live!?
You will have to think with your head and pull out all the elements of the sum of the arithmetic progression from the condition. We know what two-digit numbers are. They consist of two numbers.) What two-digit number will be first? 10, presumably.) A last thing double digit number? 99, of course! The three-digit ones will follow him...
Multiples of three... Hm... These are numbers that are divisible by three, here! Ten is not divisible by three, 11 is not divisible... 12... is divisible! So, something is emerging. You can already write down a series according to the conditions of the problem:
12, 15, 18, 21, ... 96, 99.
Will this series be an arithmetic progression? Certainly! Each term differs from the previous one by strictly three. If you add 2 or 4 to a term, say, the result, i.e. the new number is no longer divisible by 3. You can immediately determine the difference of the arithmetic progression: d = 3. It will come in handy!)
So, we can safely write down some progression parameters:
What will the number be? n last member? Anyone who thinks that 99 is fatally mistaken... The numbers always go in a row, but our members jump over three. They don't match.
There are two solutions here. One way is for the super hardworking. You can write down the progression, the entire series of numbers, and count the number of members with your finger.) The second way is for the thoughtful. You need to remember the formula for the nth term. If we apply the formula to our problem, we find that 99 is the thirtieth term of the progression. Those. n = 30.
Let's look at the formula for the sum of an arithmetic progression:
We look and rejoice.) We pulled out from the problem statement everything necessary to calculate the amount:
a 1= 12.
a 30= 99.
S n = S 30.
All that remains is elementary arithmetic. We substitute the numbers into the formula and calculate:
Answer: 1665
Another type of popular puzzle:
4. Given an arithmetic progression:
-21,5; -20; -18,5; -17; ...
Find the sum of terms from twentieth to thirty-four.
We look at the formula for the amount and... we get upset.) The formula, let me remind you, calculates the amount from the first member. And in the problem you need to calculate the sum since the twentieth... The formula won't work.
You can, of course, write out the entire progression in a series, and add terms from 20 to 34. But... it’s somehow stupid and takes a long time, right?)
There is a more elegant solution. Let's divide our series into two parts. The first part will be from the first term to the nineteenth. Second part - from twenty to thirty-four. It is clear that if we calculate the sum of the terms of the first part S 1-19, let's add it with the sum of the terms of the second part S 20-34, we get the sum of the progression from the first term to the thirty-fourth S 1-34. Like this:
S 1-19 + S 20-34 = S 1-34
From this we can see that find the sum S 20-34 can be done by simple subtraction
S 20-34 = S 1-34 - S 1-19
Both amounts on the right side are considered from the first member, i.e. the standard sum formula is quite applicable to them. Let's get started?
We extract the progression parameters from the problem statement:
d = 1.5.
a 1= -21,5.
To calculate the sums of the first 19 and first 34 terms, we will need the 19th and 34th terms. We calculate them using the formula for the nth term, as in problem 2:
a 19= -21.5 +(19-1) 1.5 = 5.5
a 34= -21.5 +(34-1) 1.5 = 28
There's nothing left. From the sum of 34 terms subtract the sum of 19 terms:
S 20-34 = S 1-34 - S 1-19 = 110.5 - (-152) = 262.5
Answer: 262.5
One important note! There is a very useful trick in solving this problem. Instead of direct calculation what you need (S 20-34), we counted something that would seem not to be needed - S 1-19. And then they determined S 20-34, discarding the unnecessary from the complete result. This kind of “feint with your ears” often saves you in wicked problems.)
In this lesson we looked at problems for which it is enough to understand the meaning of the sum of an arithmetic progression. Well, you need to know a couple of formulas.)
Practical advice:
When solving any problem involving the sum of an arithmetic progression, I recommend immediately writing out the two main formulas from this topic.
Formula for the nth term:
These formulas will immediately tell you what to look for and in what direction to think in order to solve the problem. Helps.
And now the tasks for independent solution.
5. Find the sum of all two-digit numbers that are not divisible by three.
Cool?) The hint is hidden in the note to problem 4. Well, problem 3 will help.
6. The arithmetic progression is given by the condition: a 1 = -5.5; a n+1 = a n +0.5. Find the sum of its first 24 terms.
Unusual?) This is a recurrent formula. You can read about it in the previous lesson. Don’t ignore the link, such problems are often found in the State Academy of Sciences.
7. Vasya saved up money for the holiday. As much as 4550 rubles! And I decided to give my favorite person (myself) a few days of happiness). Live beautifully without denying yourself anything. Spend 500 rubles on the first day, and on each subsequent day spend 50 rubles more than the previous one! Until the money runs out. How many days of happiness did Vasya have?
Is it difficult?) The additional formula from task 2 will help.
Answers (in disarray): 7, 3240, 6.
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First level
Arithmetic progression. Detailed theory with examples (2019)
Number sequence
So, let's sit down and start writing some numbers. For example:
You can write any numbers, and there can be as many of them as you like (in our case, there are them). No matter how many numbers we write, we can always say which one is first, which one is second, and so on until the last, that is, we can number them. This is an example of a number sequence:
Number sequence
For example, for our sequence:
The assigned number is specific to only one number in the sequence. In other words, there are no three second numbers in the sequence. The second number (like the th number) is always the same.
The number with number is called the th term of the sequence.
We usually call the entire sequence by some letter (for example,), and each member of this sequence is the same letter with an index equal to the number of this member: .
In our case: 
Let's say we have a number sequence in which the difference between adjacent numbers is the same and equal.
For example: 
etc.
This number sequence is called an arithmetic progression.
The term "progression" was introduced by the Roman author Boethius back in the 6th century and was understood in a broader sense as an infinite numerical sequence. The name "arithmetic" was transferred from the theory of continuous proportions, which was studied by the ancient Greeks.
This is a number sequence, each member of which is equal to the previous one added to the same number. This number is called the difference of an arithmetic progression and is designated.
Try to determine which number sequences are an arithmetic progression and which are not:
a)
b)
c)
d)
Got it? Let's compare our answers:
Is arithmetic progression - b, c.
Is not arithmetic progression - a, d.
Let's return to the given progression () and try to find the value of its th term. Exists two way to find it.
1. Method
We can add the progression number to the previous value until we reach the th term of the progression. It’s good that we don’t have much to summarize - only three values:
So, the th term of the described arithmetic progression is equal to.
2. Method
What if we needed to find the value of the th term of the progression? The summation would take us more than one hour, and it is not a fact that we would not make mistakes when adding numbers.
Of course, mathematicians have come up with a way in which it is not necessary to add the difference of an arithmetic progression to the previous value. Take a closer look at the drawn picture... Surely you have already noticed a certain pattern, namely:
For example, let’s see what the value of the th term of this arithmetic progression consists of: 
In other words:
Try to find the value of a member of a given arithmetic progression yourself in this way.
Did you calculate? Compare your notes with the answer:
Please note that you got exactly the same number as in the previous method, when we sequentially added the terms of the arithmetic progression to the previous value.
Let’s try to “depersonalize” this formula - let’s put it in general form and get:
|
Arithmetic progression equation. |
Arithmetic progressions can be increasing or decreasing.
Increasing- progressions in which each subsequent value of the terms is greater than the previous one.
For example:
Descending- progressions in which each subsequent value of the terms is less than the previous one.
For example:
The derived formula is used in the calculation of terms in both increasing and decreasing terms of an arithmetic progression.
Let's check this in practice.
We are given an arithmetic progression consisting of the following numbers: Let's check what the th number of this arithmetic progression will be if we use our formula to calculate it:
Since then:
Thus, we are convinced that the formula operates in both decreasing and increasing arithmetic progression.
Try to find the th and th terms of this arithmetic progression yourself.
Let's compare the results:
Arithmetic progression property
Let's complicate the problem - we will derive the property of arithmetic progression.
Let's say we are given the following condition:
- arithmetic progression, find the value.
Easy, you say and start counting according to the formula you already know:
Let, ah, then:
Absolutely right. It turns out that we first find, then add it to the first number and get what we are looking for. If the progression is represented by small values, then there is nothing complicated about it, but what if we are given numbers in the condition? Agree, there is a possibility of making a mistake in the calculations.
Now think about whether it is possible to solve this problem in one step using any formula? Of course yes, and that’s what we’ll try to bring out now.
Let us denote the required term of the arithmetic progression as, the formula for finding it is known to us - this is the same formula we derived at the beginning:
, Then:
- the previous term of the progression is:
- the next term of the progression is:
Let's sum up the previous and subsequent terms of the progression:
It turns out that the sum of the previous and subsequent terms of the progression is the double value of the progression term located between them. In other words, to find the value of the progression term with known previous and subsequent values, you need to add them and divide by.
That's right, we got the same number. Let's secure the material. Calculate the value for the progression yourself, it’s not at all difficult.
Well done! You know almost everything about progression! It remains to find out only one formula, which, according to legend, was easily deduced for himself by one of the greatest mathematicians of all time, the “king of mathematicians” - Karl Gauss...
When Carl Gauss was 9 years old, a teacher, busy checking the work of students in other classes, assigned the following task in class: “Calculate the sum of all natural numbers from to (according to other sources to) inclusive.” Imagine the teacher’s surprise when one of his students (this was Karl Gauss) a minute later gave the correct answer to the task, while most of the daredevil’s classmates, after long calculations, received the wrong result...
Young Carl Gauss noticed a certain pattern that you can easily notice too.
Let's say we have an arithmetic progression consisting of -th terms: We need to find the sum of these terms of the arithmetic progression. Of course, we can manually sum all the values, but what if the task requires finding the sum of its terms, as Gauss was looking for?
Let us depict the progression given to us. Take a closer look at the highlighted numbers and try to perform various mathematical operations with them. 
Have you tried it? What did you notice? Right! Their sums are equal
Now tell me, how many such pairs are there in total in the progression given to us? Of course, exactly half of all numbers, that is.
Based on the fact that the sum of two terms of an arithmetic progression is equal, and similar pairs are equal, we obtain that the total sum is equal to:
.
Thus, the formula for the sum of the first terms of any arithmetic progression will be:
In some problems we do not know the th term, but we know the difference of the progression. Try to substitute the formula of the th term into the sum formula.
What did you get?
Well done! Now let's return to the problem that was asked to Carl Gauss: calculate for yourself what the sum of numbers starting from the th is equal to and the sum of the numbers starting from the th.
How much did you get?
Gauss found that the sum of the terms is equal, and the sum of the terms. Is that what you decided?
In fact, the formula for the sum of terms of an arithmetic progression was proven by the ancient Greek scientist Diophantus back in the 3rd century, and throughout this time, witty people made full use of the properties of an arithmetic progression.
For example, imagine Ancient Egypt and the largest construction project of that time - the construction of a pyramid... The picture shows one side of it. 
Where is the progression here, you say? Look carefully and find a pattern in the number of sand blocks in each row of the pyramid wall. 
Why not an arithmetic progression? Calculate how many blocks are needed to build one wall if block bricks are placed at the base. I hope you won’t count while moving your finger across the monitor, you remember the last formula and everything we said about arithmetic progression?
IN in this case The progression looks like this: .
Arithmetic progression difference.
The number of terms of an arithmetic progression.
Let's substitute our data into the last formulas (calculate the number of blocks in 2 ways).
Method 1.
Method 2.
And now you can calculate on the monitor: compare the obtained values with the number of blocks that are in our pyramid. Got it? Well done, you have mastered the sum of the nth terms of an arithmetic progression.
Of course, you can’t build a pyramid from blocks at the base, but from? Try to calculate how many sand bricks are needed to build a wall with this condition.
Did you manage?
The correct answer is blocks:
Training
Tasks:
- Masha is getting in shape for summer. Every day she increases the number of squats by. How many times will Masha do squats in a week if she did squats at the first training session?
- What is the sum of all odd numbers contained in.
- When storing logs, loggers stack them in such a way that each top layer contains one log less than the previous one. How many logs are in one masonry, if the foundation of the masonry is logs?
Answers:
- Let us define the parameters of the arithmetic progression. In this case
(weeks = days).Answer: In two weeks, Masha should do squats once a day.
- First odd number, last number.
Arithmetic progression difference.
The number of odd numbers in is half, however, let’s check this fact using the formula for finding the th term of an arithmetic progression:Numbers do contain odd numbers.
Let's substitute the available data into the formula:Answer: The sum of all odd numbers contained in is equal.
- Let's remember the problem about pyramids. For our case, a , since each top layer is reduced by one log, then in total there are a bunch of layers, that is.
Let's substitute the data into the formula:Answer: There are logs in the masonry.
Let's sum it up
- - a number sequence in which the difference between adjacent numbers is the same and equal. It can be increasing or decreasing.
- Finding formula The th term of an arithmetic progression is written by the formula - , where is the number of numbers in the progression.
- Property of members of an arithmetic progression- - where is the number of numbers in progression.
- The sum of the terms of an arithmetic progression can be found in two ways:
, where is the number of values.
ARITHMETIC PROGRESSION. AVERAGE LEVEL
Number sequence
Let's sit down and start writing some numbers. For example:
You can write any numbers, and there can be as many of them as you like. But we can always say which one is first, which one is second, and so on, that is, we can number them. This is an example of a number sequence.
Number sequence is a set of numbers, each of which can be assigned a unique number.
In other words, each number can be associated with a certain natural number, and a unique one. And we will not assign this number to any other number from this set.
The number with number is called the th member of the sequence.
We usually call the entire sequence by some letter (for example,), and each member of this sequence is the same letter with an index equal to the number of this member: .
It is very convenient if the th term of the sequence can be specified by some formula. For example, the formula
sets the sequence:
And the formula is the following sequence:
For example, an arithmetic progression is a sequence (the first term here is equal, and the difference is). Or (, difference).
Formula nth term
We call a formula recurrent in which, in order to find out the th term, you need to know the previous or several previous ones:
To find, for example, the th term of the progression using this formula, we will have to calculate the previous nine. For example, let it. Then:
Well, is it clear now what the formula is?
In each line we add to, multiplied by some number. Which one? Very simple: this is the number of the current member minus:
Much more convenient now, right? We check:
Decide for yourself:
In an arithmetic progression, find the formula for the nth term and find the hundredth term.
Solution:
The first term is equal. What is the difference? Here's what:
(This is why it is called difference because it is equal to the difference of successive terms of the progression).
So, the formula:
Then the hundredth term is equal to:
What is the sum of all natural numbers from to?
According to legend, the great mathematician Carl Gauss, as a 9-year-old boy, calculated this amount in a few minutes. He noticed that the sum of the first and last numbers is equal, the sum of the second and penultimate is the same, the sum of the third and 3rd from the end is the same, and so on. How many such pairs are there in total? That's right, exactly half the number of all numbers, that is. So,
The general formula for the sum of the first terms of any arithmetic progression will be:
Example:
Find the sum of all two-digit multiples.
Solution:
The first such number is this. Each subsequent number is obtained by adding to the previous number. Thus, the numbers we are interested in form an arithmetic progression with the first term and the difference.
Formula of the th term for this progression:
How many terms are there in the progression if they all have to be two-digit?
Very easy: .
The last term of the progression will be equal. Then the sum:
Answer: .
Now decide for yourself:
- Every day the athlete runs more meters than the previous day. How many total kilometers will he run in a week if he ran km m on the first day?
- A cyclist travels more kilometers every day than the previous day. On the first day he traveled km. How many days does he need to travel to cover a kilometer? How many kilometers will he travel during the last day of his journey?
- The price of a refrigerator in a store decreases by the same amount every year. Determine how much the price of a refrigerator decreased each year if, put up for sale for rubles, six years later it was sold for rubles.
Answers:
- The most important thing here is to recognize the arithmetic progression and determine its parameters. In this case, (weeks = days). You need to determine the sum of the first terms of this progression:
.
Answer: - Here it is given: , must be found.
Obviously, you need to use the same sum formula as in the previous problem:
.
Substitute the values:The root obviously doesn't fit, so the answer is.
Let's calculate the path traveled over the last day using the formula of the th term:
(km).
Answer: - Given: . Find: .
It couldn't be simpler:
(rub).
Answer:
ARITHMETIC PROGRESSION. BRIEFLY ABOUT THE MAIN THINGS
This is a number sequence in which the difference between adjacent numbers is the same and equal.
Arithmetic progression can be increasing () and decreasing ().
For example:
Formula for finding the nth term of an arithmetic progression
is written by the formula, where is the number of numbers in progression.
Property of members of an arithmetic progression
It allows you to easily find a term of a progression if its neighboring terms are known - where is the number of numbers in the progression.
Sum of terms of an arithmetic progression
There are two ways to find the amount:
Where is the number of values.
Where is the number of values.
I. V. Yakovlev | Mathematics materials | MathUs.ru
Arithmetic progression
An arithmetic progression is a special type of sequence. Therefore, before defining arithmetic (and then geometric) progression, we need to briefly discuss the important concept of number sequence.
Subsequence
Imagine a device on the screen of which certain numbers are displayed one after another. Let's say 2; 7; 13; 1; 6; 0; 3; : : : This set of numbers is precisely an example of a sequence.
Definition. A number sequence is a set of numbers in which each number can be assigned a unique number (that is, associated with a single natural number)1. The number n is called the nth term of the sequence.
So, in the example above, the first number is 2, this is the first member of the sequence, which can be denoted by a1; number five has the number 6 is the fifth term of the sequence, which can be denoted by a5. In general, the nth term of a sequence is denoted by an (or bn, cn, etc.).
A very convenient situation is when the nth term of the sequence can be specified by some formula. For example, the formula an = 2n 3 specifies the sequence: 1; 1; 3; 5; 7; : : : The formula an = (1)n specifies the sequence: 1; 1; 1; 1; : : :
Not every set of numbers is a sequence. Thus, a segment is not a sequence; it contains “too many” numbers to be renumbered. The set R of all real numbers is also not a sequence. These facts are proven in the course of mathematical analysis.
Arithmetic progression: basic definitions
Now we are ready to define an arithmetic progression.
Definition. An arithmetic progression is a sequence in which each term (starting from the second) is equal to the sum of the previous term and some fixed number (called the difference of the arithmetic progression).
For example, sequence 2; 5; 8; eleven; : : : is an arithmetic progression with first term 2 and difference 3. Sequence 7; 2; 3; 8; : : : is an arithmetic progression with first term 7 and difference 5. Sequence 3; 3; 3; : : : is an arithmetic progression with a difference equal to zero.
Equivalent definition: the sequence an is called an arithmetic progression if the difference an+1 an is a constant value (independent of n).
An arithmetic progression is called increasing if its difference is positive, and decreasing if its difference is negative.
1 But here is a more concise definition: a sequence is a function defined on the set of natural numbers. For example, a sequence of real numbers is a function f: N ! R.
By default, sequences are considered infinite, that is, containing an infinite number of numbers. But no one bothers us to consider finite sequences; in fact, any finite set of numbers can be called a finite sequence. For example, the ending sequence is 1; 2; 3; 4; 5 is made up of five numbers.
Formula for the nth term of an arithmetic progression
It is easy to understand that an arithmetic progression is completely determined by two numbers: the first term and the difference. Therefore, the question arises: how, knowing the first term and the difference, find an arbitrary term of an arithmetic progression?
It is not difficult to obtain the required formula for the nth term of an arithmetic progression. Let an
arithmetic progression with difference d. We have: | |
an+1 = an + d (n = 1; 2; : : :): | |
In particular, we write: | |
a2 = a1 + d; | |
a3 = a2 + d = (a1 + d) + d = a1 + 2d; | |
a4 = a3 + d = (a1 + 2d) + d = a1 + 3d; | |
and now it becomes clear that the formula for an is: | |
an = a1 + (n 1)d: |
Problem 1. In arithmetic progression 2; 5; 8; eleven; : : : find the formula for the nth term and calculate the hundredth term.
Solution. According to formula (1) we have:
an = 2 + 3(n 1) = 3n 1:
a100 = 3 100 1 = 299:
Property and sign of arithmetic progression
Property of arithmetic progression. In arithmetic progression an for any
In other words, each member of an arithmetic progression (starting from the second) is the arithmetic mean of its neighboring members.
Proof. We have: | ||||
a n 1+ a n+1 | (an d) + (an + d) | |||
which is what was required.
More generally, the arithmetic progression an satisfies the equality
a n = a n k+ a n+k
for any n > 2 and any natural k< n. Попробуйте самостоятельно доказать эту формулу тем же самым приёмом, что и формулу (2 ).
It turns out that formula (2) serves not only as a necessary but also as a sufficient condition for the sequence to be an arithmetic progression.
Arithmetic progression sign. If equality (2) holds for all n > 2, then the sequence an is an arithmetic progression.
Proof. Let's rewrite formula (2) as follows:
a na n 1= a n+1a n:
From this we can see that the difference an+1 an does not depend on n, and this precisely means that the sequence an is an arithmetic progression.
The property and sign of an arithmetic progression can be formulated in the form of one statement; For convenience, we will do this for three numbers (this is the situation that often occurs in problems).
Characterization of an arithmetic progression. Three numbers a, b, c form an arithmetic progression if and only if 2b = a + c.
Problem 2. (MSU, Faculty of Economics, 2007) Three numbers 8x, 3 x2 and 4 in the indicated order form a decreasing arithmetic progression. Find x and indicate the difference of this progression.
Solution. By the property of arithmetic progression we have:
2(3 x2 ) = 8x 4 , 2x2 + 8x 10 = 0 , x2 + 4x 5 = 0 , x = 1; x = 5:
If x = 1, then we get a decreasing progression of 8, 2, 4 with a difference of 6. If x = 5, then we get an increasing progression of 40, 22, 4; this case is not suitable.
Answer: x = 1, the difference is 6.
Sum of the first n terms of an arithmetic progression
Legend has it that one day the teacher told the children to find the sum of the numbers from 1 to 100 and sat down quietly to read the newspaper. However, within a few minutes, one boy said that he had solved the problem. This was 9-year-old Carl Friedrich Gauss, later one of the greatest mathematicians in history.
Little Gauss's idea was as follows. Let
S = 1 + 2 + 3 + : : : + 98 + 99 + 100:
Let's write this amount in reverse order:
S = 100 + 99 + 98 + : : : + 3 + 2 + 1;
and add these two formulas:
2S = (1 + 100) + (2 + 99) + (3 + 98) + : : : + (98 + 3) + (99 + 2) + (100 + 1):
Each term in brackets is equal to 101, and there are 100 such terms in total. Therefore
2S = 101 100 = 10100;
We use this idea to derive the sum formula
S = a1 + a2 + : : : + an + a n n: (3)
A useful modification of formula (3) is obtained if we substitute the formula of the nth term an = a1 + (n 1)d into it:
2a1 + (n 1)d | |||||
Problem 3. Find the sum of all positive three-digit numbers divisible by 13.
Solution. Three-digit numbers that are multiples of 13 form an arithmetic progression with the first term being 104 and the difference being 13; The nth term of this progression has the form:
an = 104 + 13(n 1) = 91 + 13n:
Let's find out how many terms our progression contains. To do this, we solve the inequality:
an 6 999; 91 + 13n 6 999;
n 6 908 13 = 6911 13 ; n 6 69:
So, there are 69 members in our progression. Using formula (4) we find the required amount:
S = 2 104 + 68 13 69 = 37674: 2
First level
Arithmetic progression. Detailed theory with examples (2019)
Number sequence
So, let's sit down and start writing some numbers. For example:
You can write any numbers, and there can be as many of them as you like (in our case, there are them). No matter how many numbers we write, we can always say which one is first, which one is second, and so on until the last, that is, we can number them. This is an example of a number sequence:
Number sequence
For example, for our sequence:
The assigned number is specific to only one number in the sequence. In other words, there are no three second numbers in the sequence. The second number (like the th number) is always the same.
The number with number is called the th term of the sequence.
We usually call the entire sequence by some letter (for example,), and each member of this sequence is the same letter with an index equal to the number of this member: .
In our case:
Let's say we have a number sequence in which the difference between adjacent numbers is the same and equal.
For example:
etc.
This number sequence is called an arithmetic progression.
The term "progression" was introduced by the Roman author Boethius back in the 6th century and was understood in a broader sense as an infinite numerical sequence. The name "arithmetic" was transferred from the theory of continuous proportions, which was studied by the ancient Greeks.
This is a number sequence, each member of which is equal to the previous one added to the same number. This number is called the difference of an arithmetic progression and is designated.
Try to determine which number sequences are an arithmetic progression and which are not:
a)
b)
c)
d)
Got it? Let's compare our answers:
Is arithmetic progression - b, c.
Is not arithmetic progression - a, d.
Let's return to the given progression () and try to find the value of its th term. Exists two way to find it.
1. Method
We can add the progression number to the previous value until we reach the th term of the progression. It’s good that we don’t have much to summarize - only three values:
So, the th term of the described arithmetic progression is equal to.
2. Method
What if we needed to find the value of the th term of the progression? The summation would take us more than one hour, and it is not a fact that we would not make mistakes when adding numbers.
Of course, mathematicians have come up with a way in which it is not necessary to add the difference of an arithmetic progression to the previous value. Take a closer look at the drawn picture... Surely you have already noticed a certain pattern, namely:
For example, let’s see what the value of the th term of this arithmetic progression consists of:
In other words:
Try to find the value of a member of a given arithmetic progression yourself in this way.
Did you calculate? Compare your notes with the answer:
Please note that you got exactly the same number as in the previous method, when we sequentially added the terms of the arithmetic progression to the previous value.
Let’s try to “depersonalize” this formula - let’s put it in general form and get:
|
Arithmetic progression equation. |
Arithmetic progressions can be increasing or decreasing.
Increasing- progressions in which each subsequent value of the terms is greater than the previous one.
For example:
Descending- progressions in which each subsequent value of the terms is less than the previous one.
For example:
The derived formula is used in the calculation of terms in both increasing and decreasing terms of an arithmetic progression.
Let's check this in practice.
We are given an arithmetic progression consisting of the following numbers: Let's check what the th number of this arithmetic progression will be if we use our formula to calculate it:
Since then:
Thus, we are convinced that the formula operates in both decreasing and increasing arithmetic progression.
Try to find the th and th terms of this arithmetic progression yourself.
Let's compare the results:
Arithmetic progression property
Let's complicate the problem - we will derive the property of arithmetic progression.
Let's say we are given the following condition:
- arithmetic progression, find the value.
Easy, you say and start counting according to the formula you already know:
Let, ah, then:
Absolutely right. It turns out that we first find, then add it to the first number and get what we are looking for. If the progression is represented by small values, then there is nothing complicated about it, but what if we are given numbers in the condition? Agree, there is a possibility of making a mistake in the calculations.
Now think about whether it is possible to solve this problem in one step using any formula? Of course yes, and that’s what we’ll try to bring out now.
Let us denote the required term of the arithmetic progression as, the formula for finding it is known to us - this is the same formula we derived at the beginning:
, Then:
- the previous term of the progression is:
- the next term of the progression is:
Let's sum up the previous and subsequent terms of the progression:
It turns out that the sum of the previous and subsequent terms of the progression is the double value of the progression term located between them. In other words, to find the value of the progression term with known previous and subsequent values, you need to add them and divide by.
That's right, we got the same number. Let's secure the material. Calculate the value for the progression yourself, it’s not at all difficult.
Well done! You know almost everything about progression! It remains to find out only one formula, which, according to legend, was easily deduced for himself by one of the greatest mathematicians of all time, the “king of mathematicians” - Karl Gauss...
When Carl Gauss was 9 years old, a teacher, busy checking the work of students in other classes, assigned the following task in class: “Calculate the sum of all natural numbers from to (according to other sources to) inclusive.” Imagine the teacher’s surprise when one of his students (this was Karl Gauss) a minute later gave the correct answer to the task, while most of the daredevil’s classmates, after long calculations, received the wrong result...
Young Carl Gauss noticed a certain pattern that you can easily notice too.
Let's say we have an arithmetic progression consisting of -th terms: We need to find the sum of these terms of the arithmetic progression. Of course, we can manually sum all the values, but what if the task requires finding the sum of its terms, as Gauss was looking for?
Let us depict the progression given to us. Take a closer look at the highlighted numbers and try to perform various mathematical operations with them.
Have you tried it? What did you notice? Right! Their sums are equal
Now tell me, how many such pairs are there in total in the progression given to us? Of course, exactly half of all numbers, that is.
Based on the fact that the sum of two terms of an arithmetic progression is equal, and similar pairs are equal, we obtain that the total sum is equal to:
.
Thus, the formula for the sum of the first terms of any arithmetic progression will be:
In some problems we do not know the th term, but we know the difference of the progression. Try to substitute the formula of the th term into the sum formula.
What did you get?
Well done! Now let's return to the problem that was asked to Carl Gauss: calculate for yourself what the sum of numbers starting from the th is equal to and the sum of the numbers starting from the th.
How much did you get?
Gauss found that the sum of the terms is equal, and the sum of the terms. Is that what you decided?
In fact, the formula for the sum of terms of an arithmetic progression was proven by the ancient Greek scientist Diophantus back in the 3rd century, and throughout this time, witty people made full use of the properties of an arithmetic progression.
For example, imagine Ancient Egypt and the largest construction project of that time - the construction of a pyramid... The picture shows one side of it.
Where is the progression here, you say? Look carefully and find a pattern in the number of sand blocks in each row of the pyramid wall.
Why not an arithmetic progression? Calculate how many blocks are needed to build one wall if block bricks are placed at the base. I hope you won’t count while moving your finger across the monitor, you remember the last formula and everything we said about arithmetic progression?
In this case, the progression looks like this: .
Arithmetic progression difference.
The number of terms of an arithmetic progression.
Let's substitute our data into the last formulas (calculate the number of blocks in 2 ways).
Method 1.
Method 2.
And now you can calculate on the monitor: compare the obtained values with the number of blocks that are in our pyramid. Got it? Well done, you have mastered the sum of the nth terms of an arithmetic progression.
Of course, you can’t build a pyramid from blocks at the base, but from? Try to calculate how many sand bricks are needed to build a wall with this condition.
Did you manage?
The correct answer is blocks:
Training
Tasks:
- Masha is getting in shape for summer. Every day she increases the number of squats by. How many times will Masha do squats in a week if she did squats at the first training session?
- What is the sum of all odd numbers contained in.
- When storing logs, loggers stack them in such a way that each top layer contains one log less than the previous one. How many logs are in one masonry, if the foundation of the masonry is logs?
Answers:
- Let us define the parameters of the arithmetic progression. In this case
(weeks = days).Answer: In two weeks, Masha should do squats once a day.
- First odd number, last number.
Arithmetic progression difference.
The number of odd numbers in is half, however, let’s check this fact using the formula for finding the th term of an arithmetic progression:Numbers do contain odd numbers.
Let's substitute the available data into the formula:Answer: The sum of all odd numbers contained in is equal.
- Let's remember the problem about pyramids. For our case, a , since each top layer is reduced by one log, then in total there are a bunch of layers, that is.
Let's substitute the data into the formula:Answer: There are logs in the masonry.
Let's sum it up
- - a number sequence in which the difference between adjacent numbers is the same and equal. It can be increasing or decreasing.
- Finding formula The th term of an arithmetic progression is written by the formula - , where is the number of numbers in the progression.
- Property of members of an arithmetic progression- - where is the number of numbers in progression.
- The sum of the terms of an arithmetic progression can be found in two ways:
, where is the number of values.
ARITHMETIC PROGRESSION. AVERAGE LEVEL
Number sequence
Let's sit down and start writing some numbers. For example:
You can write any numbers, and there can be as many of them as you like. But we can always say which one is first, which one is second, and so on, that is, we can number them. This is an example of a number sequence.
Number sequence is a set of numbers, each of which can be assigned a unique number.
In other words, each number can be associated with a certain natural number, and a unique one. And we will not assign this number to any other number from this set.
The number with number is called the th member of the sequence.
We usually call the entire sequence by some letter (for example,), and each member of this sequence is the same letter with an index equal to the number of this member: .
It is very convenient if the th term of the sequence can be specified by some formula. For example, the formula
sets the sequence:
And the formula is the following sequence:
For example, an arithmetic progression is a sequence (the first term here is equal, and the difference is). Or (, difference).
Formula nth term
We call a formula recurrent in which, in order to find out the th term, you need to know the previous or several previous ones:
To find, for example, the th term of the progression using this formula, we will have to calculate the previous nine. For example, let it. Then:
Well, is it clear now what the formula is?
In each line we add to, multiplied by some number. Which one? Very simple: this is the number of the current member minus:
Much more convenient now, right? We check:
Decide for yourself:
In an arithmetic progression, find the formula for the nth term and find the hundredth term.
Solution:
The first term is equal. What is the difference? Here's what:
(This is why it is called difference because it is equal to the difference of successive terms of the progression).
So, the formula:
Then the hundredth term is equal to:
What is the sum of all natural numbers from to?
According to legend, the great mathematician Carl Gauss, as a 9-year-old boy, calculated this amount in a few minutes. He noticed that the sum of the first and last numbers is equal, the sum of the second and penultimate is the same, the sum of the third and 3rd from the end is the same, and so on. How many such pairs are there in total? That's right, exactly half the number of all numbers, that is. So,
The general formula for the sum of the first terms of any arithmetic progression will be:
Example:
Find the sum of all two-digit multiples.
Solution:
The first such number is this. Each subsequent number is obtained by adding to the previous number. Thus, the numbers we are interested in form an arithmetic progression with the first term and the difference.
Formula of the th term for this progression:
How many terms are there in the progression if they all have to be two-digit?
Very easy: .
The last term of the progression will be equal. Then the sum:
Answer: .
Now decide for yourself:
- Every day the athlete runs more meters than the previous day. How many total kilometers will he run in a week if he ran km m on the first day?
- A cyclist travels more kilometers every day than the previous day. On the first day he traveled km. How many days does he need to travel to cover a kilometer? How many kilometers will he travel during the last day of his journey?
- The price of a refrigerator in a store decreases by the same amount every year. Determine how much the price of a refrigerator decreased each year if, put up for sale for rubles, six years later it was sold for rubles.
Answers:
- The most important thing here is to recognize the arithmetic progression and determine its parameters. In this case, (weeks = days). You need to determine the sum of the first terms of this progression:
.
Answer: - Here it is given: , must be found.
Obviously, you need to use the same sum formula as in the previous problem:
.
Substitute the values:The root obviously doesn't fit, so the answer is.
Let's calculate the path traveled over the last day using the formula of the th term:
(km).
Answer: - Given: . Find: .
It couldn't be simpler:
(rub).
Answer:
ARITHMETIC PROGRESSION. BRIEFLY ABOUT THE MAIN THINGS
This is a number sequence in which the difference between adjacent numbers is the same and equal.
Arithmetic progression can be increasing () and decreasing ().
For example:
Formula for finding the nth term of an arithmetic progression
is written by the formula, where is the number of numbers in progression.
Property of members of an arithmetic progression
It allows you to easily find a term of a progression if its neighboring terms are known - where is the number of numbers in the progression.
Sum of terms of an arithmetic progression
There are two ways to find the amount:
Where is the number of values.
Where is the number of values.
Many people have heard about arithmetic progression, but not everyone has a good idea of what it is. In this article we will give the corresponding definition, and also consider the question of how to find the difference of an arithmetic progression, and give a number of examples.
Mathematical definition
So, if we are talking about an arithmetic or algebraic progression (these concepts define the same thing), then this means that there is a certain number series that satisfies the following law: every two adjacent numbers in the series differ by the same value. Mathematically it is written like this:
Here n means the number of element a n in the sequence, and the number d is the difference of the progression (its name follows from the presented formula).
What does knowing the difference d mean? About how “far” neighboring numbers are from each other. However, knowledge of d is a necessary but not sufficient condition for determining (restoring) the entire progression. You need to know one more number, which can be absolutely any element of the series under consideration, for example, a 4, a10, but, as a rule, they use the first number, that is, a 1.
Formulas for determining progression elements
In general, the information above is already enough to move on to solving specific problems. Nevertheless, before the arithmetic progression is given, and it will be necessary to find its difference, we will present a couple of useful formulas, thereby facilitating the subsequent process of solving problems.
It is easy to show that any element of the sequence with number n can be found as follows:
a n = a 1 + (n - 1) * d
Indeed, anyone can check this formula by simple search: if you substitute n = 1, you get the first element, if you substitute n = 2, then the expression gives the sum of the first number and the difference, and so on.
The conditions of many problems are composed in such a way that, given a known pair of numbers, the numbers of which are also given in the sequence, it is necessary to reconstruct the entire number series (find the difference and the first element). Now we will solve this problem in general form.
So, let two elements with numbers n and m be given. Using the formula obtained above, you can create a system of two equations:
a n = a 1 + (n - 1) * d;
a m = a 1 + (m - 1) * d
To find unknown quantities, we will use a well-known simple technique for solving such a system: subtract the left and right sides in pairs, the equality will remain valid. We have:
a n = a 1 + (n - 1) * d;
a n - a m = (n - 1) * d - (m - 1) * d = d * (n - m)
Thus, we have excluded one unknown (a 1). Now we can write the final expression for determining d:
d = (a n - a m) / (n - m), where n > m
We received a very simple formula: in order to calculate the difference d in accordance with the conditions of the problem, it is only necessary to take the ratio of the differences between the elements themselves and their serial numbers. One important point should be paid attention to: the differences are taken between the “senior” and “junior” members, that is, n > m (“senior” means standing further from the beginning of the sequence, its absolute value can be either greater or less more "junior" element).
The expression for the difference d progression should be substituted into any of the equations at the beginning of solving the problem to obtain the value of the first term.
In our age of computer technology development, many schoolchildren try to find solutions for their assignments on the Internet, so questions of this type often arise: find the difference of an arithmetic progression online. For such a request, the search engine will return a number of web pages, by going to which you will need to enter the data known from the condition (this can be either two terms of the progression or the sum of a certain number of them) and instantly receive an answer. However, this approach to solving the problem is unproductive in terms of the student’s development and understanding of the essence of the task assigned to him.
Solution without using formulas
Let's solve the first problem without using any of the given formulas. Let the elements of the series be given: a6 = 3, a9 = 18. Find the difference of the arithmetic progression.
Known elements stand close to each other in a row. How many times must the difference d be added to the smallest to get the largest? Three times (the first time adding d, we get the 7th element, the second time - the eighth, and finally, the third time - the ninth). What number must be added to three three times to get 18? This is the number five. Really:
Thus, the unknown difference d = 5.
Of course, the solution could have been carried out using the appropriate formula, but this was not done intentionally. A detailed explanation of the solution to the problem should become a clear and clear example of what an arithmetic progression is.
A task similar to the previous one
Now let's solve a similar problem, but change the input data. So, you should find if a3 = 2, a9 = 19.
Of course, you can again resort to the “head-on” solution method. But since the elements of the series are given, which are relatively far from each other, this method will not be entirely convenient. But using the resulting formula will quickly lead us to the answer:
d = (a 9 - a 3) / (9 - 3) = (19 - 2) / (6) = 17 / 6 ≈ 2.83
Here we have rounded the final number. The extent to which this rounding led to an error can be judged by checking the result obtained:
a 9 = a 3 + 2.83 + 2.83 + 2.83 + 2.83 + 2.83 + 2.83 = 18.98
This result differs by only 0.1% from the value given in the condition. Therefore, the rounding used to the nearest hundredths can be considered a successful choice.
Problems involving applying the formula for the an term
Let's consider a classic example of a problem to determine the unknown d: find the difference of an arithmetic progression if a1 = 12, a5 = 40.
When two numbers of an unknown algebraic sequence are given, and one of them is the element a 1, then you do not need to think long, but should immediately apply the formula for the a n term. In this case we have:
a 5 = a 1 + d * (5 - 1) => d = (a 5 - a 1) / 4 = (40 - 12) / 4 = 7
We received the exact number when dividing, so there is no point in checking the accuracy of the calculated result, as was done in the previous paragraph.
Let's solve another similar problem: we need to find the difference of an arithmetic progression if a1 = 16, a8 = 37.
We use an approach similar to the previous one and get:
a 8 = a 1 + d * (8 - 1) => d = (a 8 - a 1) / 7 = (37 - 16) / 7 = 3
What else should you know about arithmetic progression?
In addition to problems of finding an unknown difference or individual elements, it is often necessary to solve problems of the sum of the first terms of a sequence. Consideration of these problems is beyond the scope of the article, however, for completeness of information, we present a general formula for the sum of n numbers in a series:
∑ n i = 1 (a i) = n * (a 1 + a n) / 2
