Numerical segments, intervals, half-intervals and rays are called numerical intervals. Number spans How to write a number span
Among the number sets, that is sets, whose objects are numbers, distinguish the so-called number gaps. Their value is that it is very easy to imagine a set corresponding to a specified numerical range, and vice versa. Therefore, with their help it is convenient to write down the set of solutions of the inequality.
In this article, we will analyze all types of numerical intervals. Here we give their names, introduce notation, draw numerical intervals on the coordinate line, and also show which simplest inequalities correspond to them. In conclusion, we will visually present all the information in the form of a table of numerical intervals.
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Types of numerical intervals
Each numerical interval has four inextricably linked things:
- the name of the number range,
- corresponding inequality or double inequality,
- designation,
- and its geometric image in the form of an image on a coordinate line.
Any numerical interval can be specified in any of the last three ways in the list: either by an inequality, or by a designation, or by its image on a coordinate line. And according to this method tasks, for example, by inequality, others are easily restored (in our case, the notation and the geometric image).
Let's get down to specifics. Let us describe all the numerical intervals on the four sides indicated above.
Let's start with a description of the numerical interval, called open number beam . Note that the adjective "numerical" is often omitted, leaving the name open beam.
This numerical interval corresponds to the simplest inequalities with one variable of the form x a , where a is some real number. That is, according to the meaning of the written inequalities, the open number ray is made up of all that are less than the number a (in the case of the inequality x a).
The set of numbers satisfying the inequality x a , like (a, +∞) .
It remains to show the geometric image of the open beam, it will become clear from it that the considered numerical interval received such a name not by chance. Let's turn to. It is known that there is a one-to-one correspondence between its points and real numbers, which allows the coordinate line to be called the number line. And when talking about comparing numbers we noted that the larger number is located on the coordinate line to the right of the smaller one, and the smaller one is to the left of the larger one. Based on these considerations, the inequality x a - points lying to the right of point a . The number a itself does not satisfy these inequalities, in order to emphasize this in the drawing, it is depicted as a dot with an empty center. Above the points, which correspond to numbers that satisfy the inequality, depict oblique shading:
From the above drawings, it can be seen that these numerical intervals correspond to parts of the number line, which are rays starting at point a , but excluding point a itself. In other words, they are rays without a beginning. Hence the name - open number beam.
Let us give some concrete examples of open numerical rays. Thus, the strict inequality x>−3 defines an open number ray. It is also defined by the notation (−3, ∞) . And on the coordinate line, this numerical interval is a set of points lying to the right of the point with coordinate −3, not including this point itself. Another example: inequality x<2,3
, как и запись (−∞, 2,3)
, задает открытый числовой луч, который следующим образом изображается на координатной прямой
We pass to the numerical intervals of the following form - number rays. Geometrically, they differ from open beams in that the beginning of the beam is not discarded. In other words, the geometric image of numerical intervals of this type is a full-fledged ray.
As for specifying numerical rays using inequalities, they correspond to non-strict inequalities x≤a or x≥a . They are denoted by (−∞, a] and . And the geometric image of a numerical segment is a segment together with its ends:
For example, a numerical segment, which is given by a double inequality, can be denoted as , on the coordinate line it corresponds to a segment with ends at points having coordinates root of two and root of three.
It remains only to say about the numerical intervals called half-intervals. They represent, so to speak, an intermediate option between an interval and a segment, since they include one of the boundary points. The half-intervals are given by double inequalities a
Table of numerical intervals
So, in the previous paragraph, we defined and described the following numerical intervals:
- open number beam;
- number beam;
- interval;
- half-interval.
For convenience, we summarize all the data on numerical intervals in a table. Let's put in it the name of the numerical interval, the inequality corresponding to it, the notation and the image on the coordinate line. We get the following range table:
Bibliography.
- Algebra: textbook for 8 cells. general education institutions / [Yu. N. Makarychev, N. G. Mindyuk, K. I. Neshkov, S. B. Suvorova]; ed. S. A. Telyakovsky. - 16th ed. - M. : Education, 2008. - 271 p. : ill. - ISBN 978-5-09-019243-9.
- Mordkovich A. G. Algebra. Grade 9 At 2 pm Part 1. Textbook for students of educational institutions / A. G. Mordkovich, P. V. Semenov. - 13th ed., Sr. - M.: Mnemosyne, 2011. - 222 p.: ill. ISBN 978-5-346-01752-3.
Answer - The set (-∞;+∞) is called a number line, and any number is called a point of this line. Let a be an arbitrary point on the real line and δ
Positive number. The interval (a-δ; a+δ) is called the δ-neighborhood of the point a.
The set X is bounded from above (from below) if there is such a number c that for any x ∈ X the inequality x≤с (x≥c) is satisfied. The number c in this case is called the upper (lower) bound of the set X. A set bounded both above and below is called bounded. The smallest (largest) of the upper (lower) faces of a set is called the exact upper (lower) bound of this set.
A numerical interval is a connected set of real numbers, that is, such that if 2 numbers belong to this set, then all the numbers enclosed between them also belong to this set. There are several, in a sense, different types of non-empty numerical intervals: Line, open ray, closed ray, line segment, half-interval, interval
Number line
The set of all real numbers is also called the number line. They write.
In practice, there is no need to distinguish between the concept of a coordinate or number line in the geometric sense and the concept of a number line introduced by this definition. Therefore, these different concepts are denoted by the same term.
open beam
The set of numbers such that or is called an open number ray. Write or respectively: .
closed beam
The set of numbers such that or is called a closed number ray. Write or respectively:
The set of numbers such that is called a number segment.
Comment. The definition does not state that . It is assumed that the case is possible. Then the numerical interval turns into a point.
Interval
A set of numbers such as is called a numerical interval.
Comment. The coincidence of the designations of an open beam, a straight line and an interval is not accidental. An open ray can be understood as an interval, one of the ends of which is removed to infinity, and a number line - as an interval, both ends of which are removed to infinity.
Half interval
The set of numbers such that or is called a numerical half-interval.
Write or, respectively,
3.Function.Function graph. Ways to set a function.
Answer - If two variables x and y are given, then they say that the variable y is a function of the variable x, if such a relationship between these variables is given that allows for each value to uniquely determine the value of y.
The notation F = y(x) means that we are considering a function that allows for any value of the independent variable x (out of those that the argument x can take at all) to find the corresponding value of the dependent variable y.
Ways to set a function.
A function can be defined by a formula, for example:
y \u003d 3x2 - 2.
The function can be given by a graph. Using the graph, you can determine which value of the function corresponds to the specified value of the argument. Usually this is an approximate value of the function.
4. The main characteristics of the function: monotonicity, parity, periodicity.
Answer - Periodicity Definition. A function f is called periodic if there exists such a number
, that f(x+
)=f(x), for all x D(f). Naturally, there are an infinite number of such numbers. The smallest positive number ^ T is called the period of the function. Examples. A. y \u003d cos x, T \u003d 2 . B. y \u003d tg x, T \u003d . S. y = (x), T = 1. D. y = , this function is not periodic. Parity Definition. A function f is called even if for all x from D(f) the property f(-x) = f(x) is satisfied. If f (-x) = -f (x), then the function is called odd. If none of these relations is satisfied, then the function is called a function of general form. Examples. A. y \u003d cos (x) - even; B. y \u003d tg (x) - odd; S. y \u003d (x); y=sin(x+1) – general functions. Monotony Definition. A function f: X -> R is called increasing (decreasing) if for any
condition is met:
Definition. A function X -> R is said to be monotonic on X if it is increasing or decreasing on X. If f is monotone on some subsets of X, then it is called piecewise monotone. Example. y \u003d cos x is a piecewise monotone function.
Number intervals include rays, segments, intervals and half-intervals.
Types of numerical intervals
Name | Image | Inequality | Designation |
---|---|---|---|
open beam | x > a | (a; +∞) | |
x < a | (-∞; a) | ||
closed beam | x ⩾ a | [a; +∞) | |
x ⩽ a | (-∞; a] | ||
Line segment | a ⩽ x ⩽ b | [a; b] | |
Interval | a < x < b | (a; b) | |
Half interval | a < x ⩽ b | (a; b] | |
a ⩽ x < b | [a; b) |
Table a and b are the boundary points, and x- a variable that can take the coordinate of any point belonging to the numerical interval.
boundary point is a point that defines the boundary of the numerical interval. The boundary point may or may not belong to the numerical interval. In the drawings, boundary points that do not belong to the numerical interval under consideration are indicated by an unfilled circle, and those belonging to a filled circle.
Open and closed beam
open beam is a set of points on a line that lie on one side of a boundary point that is not included in the given set. A ray is called open precisely because of the boundary point, which does not belong to it.
Consider the set of points on the coordinate line that have a coordinate greater than 2, and, therefore, located to the right of point 2:
Such a set can be defined by the inequality x> 2. Open beams are denoted with parentheses - (2; +∞), this entry reads as follows: an open numerical beam from two to plus infinity.
The set corresponding to the inequality x < 2, можно обозначить (-∞; 2) или изобразить в виде луча, все точки которого лежат с левой стороны от точки 2:
closed beam is the set of points on a line that lie on the same side of a boundary point belonging to the given set. In the drawings, the boundary points belonging to the set under consideration are indicated by a filled circle.
Closed numerical rays are defined by non-strict inequalities. For example, the inequalities x 2 and x 2 can be shown like this:
These closed rays are designated as follows: , it is read like this: a numerical ray from two to plus infinity and a numerical ray from minus infinity to two. The square bracket in the notation indicates that point 2 belongs to the numerical gap.
Line segment
Line segment is the set of points on a line that lie between two boundary points belonging to the given set. Such sets are given by double non-strict inequalities.
Consider a segment of the coordinate line with ends at points -2 and 3:
The set of points that make up a given segment can be specified by the double inequality -2 x 3 or denote [-2; 3], such an entry reads as follows: a segment from minus two to three.
Interval and half-interval
Interval is the set of points on a line that lie between two boundary points that do not belong to the given set. Such sets are defined by double strict inequalities.
Consider a segment of the coordinate line with ends at points -2 and 3:
The set of points that make up this interval can be specified by the double inequality -2< x < 3 или обозначить (-2; 3). Такая запись читается так: интервал от минус двух до трёх.
Half interval is the set of points on a line that lie between two boundary points, one of which belongs to the set and the other does not. Such sets are given by double inequalities:
These half-intervals are designated as follows: (-2; 3] and [-2; 3). It reads like this: a half-interval from minus two to three, including 3, and a half-interval from minus two to three, including minus two.
"Tables in algebra grade 7" - The difference of squares. Expressions. Content. Algebra tables.
"Numerical functions" - The set X is called the task area or the area of \u200b\u200bdefinition of the function f and is denoted by D (f). Function graph. However, not every line is a graph of some function. Example 1. A skydiver jumps from a hovering helicopter. Just one number. Piecewise specification of functions. Natural phenomena are closely related to each other.
"Numeric sequences" - Lesson-conference. "Number Sequences". Geometric progression. Task methods. Arithmetic progression. Numeric sequences.
"Limit of a numerical sequence" - Solution: Methods for specifying sequences. Limited number sequence. The value уn is called the common member of the sequence. The limit of the numerical sequence. Continuity of a function at a point. Example: 1, 4, 9, 16, ..., n2, ... - limited from below 1. By setting an analytical formula. Limit properties.
"Number Sequence" - Numeric Sequence ( number series): numbers written out in a certain order. 2. Methods for setting sequences. 1. Definition. Sequence notation. Sequences. 1. Formula of the n-th member of the sequence: - allows you to find any member of the sequence. 3. Graph of the numerical sequence.
"Tables" - Oil and gas production. Table 2. Table 5. Tabular information models. Order of construction of OS type table. Table 4. Annual estimates. Table number. Tables of the type "Objects - objects". Pupils of 10 "B" class. Table structure. Tables of type objects-properties. Pairs of objects are described; There is only one property.
B) Number line
Consider the number line (Fig. 6):
Consider the set of rational numbers
Each rational number is represented by some point on the number line. So, the numbers are marked in the figure.
Let's prove that .
Proof. Let there be a fraction : . We have the right to consider this fraction irreducible. Since , then - the number is even: - odd. Substituting instead of its expression, we find: , from which it follows that - even number. We have obtained a contradiction, which proves the assertion.
So, not all points of the number axis represent rational numbers. Those dots that do not represent rational numbers represent numbers called irrational.
Any number of the form , , is either integer or irrational.
Numeric spans
Numerical segments, intervals, half-intervals and rays are called numerical intervals.
Inequality defining a numerical gap | Number gap notation | The name of the number range | It reads like this: |
a ≤ x ≤ b | [a; b] | Numerical segment | Segment from a to b |
a< x < b | (a; b) | Interval | Interval from a to b |
a ≤ x< b | [a; b) | Half interval | Half interval from a before b, including a. |
a< x ≤ b | (a; b] | Half interval | Half interval from a before b, including b. |
x ≥ a | [a; +∞) | number beam | Number beam from a up to plus infinity |
x > a | (a; +∞) | Open number beam | Open number beam from a up to plus infinity |
x ≤ a | (-∞; a] | number beam | Number ray from minus infinity to a |
x< a | (-∞; a) | Open number beam | Open number ray from minus infinity to a |
Let's represent on the coordinate line the numbers a and b, as well as the number x between them.
The set of all numbers that meet the condition a ≤ x ≤ b, is called numerical segment or just a cut. It is marked like this: a; b]-It reads like this: a segment from a to b.
The set of numbers that meet the condition a< x < b , is called interval. It's marked like this: a; b)
It reads like this: the interval from a to b.
Sets of numbers satisfying the conditions a ≤ x< b или a<x ≤ b, are called half-intervals. Designations:
Set a ≤ x< b обозначается так:[a; b), is read like this: a half-interval from a before b, including a.
Lots of a<x ≤ b marked like this: a; b], reads like this: a half-interval from a before b, including b.
Now imagine Ray with a dot a, to the right and left of which is a set of numbers.
a, satisfying the condition x ≥ a, is called number beam.
It is marked like this: a; +∞) - It reads like this: a numerical beam from a up to plus infinity.
Lots of numbers to the right of the dot a corresponding to the inequality x > a, is called open number beam.
It's marked like this: a; +∞) - It reads like this: an open numerical beam from a up to plus infinity.
a, satisfying the condition x ≤ a, is called number line from minus infinity toa .
It's labeled like this: -∞; a]-It reads like this: a numerical ray from minus infinity to a.
Set of numbers to the left of the dot a corresponding to the inequality x< a , is called open numerical beam from minus infinity toa .
It's marked like this: -∞; a) - It reads like this: an open numerical ray from minus infinity to a.
The set of real numbers is represented by the entire coordinate line. He is called number line. It's labeled like this: - ∞; + ∞ )
3) Linear equations and inequalities with one variable, their solutions:
An equation containing a variable is called an equation with one variable, or an equation with one unknown. For example, an equation with one variable is 3(2x+7)=4x-1.
The root or solution of an equation is the value of a variable at which the equation becomes a true numerical equality. For example, the number 1 is the solution to the equation 2x+5=8x-1. The equation x2+1=0 has no solution, because the left side of the equation is always greater than zero. The equation (x+3)(x-4)=0 has two roots: x1= -3, x2=4.
Solving an equation means finding all its roots or proving that there are no roots.
Equations are called equivalent if all roots of the first equation are roots of the second equation and vice versa, all roots of the second equation are roots of the first equation, or if both equations have no roots. For example, the equations x-8=2 and x+10=20 are equivalent, because the root of the first equation x=10 is also the root of the second equation, and both equations have the same root.
When solving equations, the following properties are used:
If in the equation we transfer the term from one part to another by changing its sign, then we will get an equation equivalent to the given one.
If both sides of the equation are multiplied or divided by the same non-zero number, then an equation is obtained that is equivalent to the given one.
The equation ax=b, where x is a variable and a and b are some numbers, is called a linear equation with one variable.
If a¹0, then the equation has a unique solution.
If a=0, b=0, then any value of x satisfies the equation.
If a=0, b¹0, then the equation has no solutions, because 0x=b is not executed for any value of the variable.
Example 1. Solve the equation: -8(11-2x)+40=3(5x-4)
Let's open the brackets in both parts of the equation, move all the terms with x to the left side of the equation, and the terms that do not contain x to the right side, we get:
16x-15x=88-40-12
Example 2. Solve equations:
x3-2x2-98x+18=0;
These equations are not linear, but we will show how such equations can be solved.
3x2-5x=0; x(3x-5)=0. The product is equal to zero, if one of the factors is equal to zero, we get x1=0; x2= .
Answer: 0; .
Factoring the left side of the equation:
x2(x-2)-9(x-2)=(x-2)(x2-9)=(x-2)(x-3)(x-3), i.e. (x-2)(x-3)(x+3)=0. This shows that the solutions of this equation are the numbers x1=2, x2=3, x3=-3.
c) Let's represent 7x as 3x+4x, then we have: x2+3x+4x+12=0, x(x+3)+4(x+3)=0, (x+3)(x+4)= 0, hence x1=-3, x2=-4.
Answer: -3; - four.
Example 3. Solve the equation: ½x+1ç+½x-1ç=3.
Recall the definition of the modulus of a number:
For example: ½3½=3, ½0½=0, ½-4½= 4.
In this equation, under the module sign are the numbers x-1 and x + 1. If x is less than -1, then x+1 is negative, then ½x+1½=-x-1. And if x>-1, then ½x+1½=x+1. For x=-1 ½x+1½=0.
In this way,
Similarly
a) Consider given equation½x+1½+½x-1½=3 for x£-1, it is equivalent to the equation -x-1-x+1=3, -2x=3, x= , this number belongs to the set x£-1.
b) Let -1< х £ 1, тогда данное уравнение равносильно уравнению х+1-х+1=3, 2¹3 уравнение не имеет решения на данном множестве.
c) Consider the case x>1.
x+1+x-1=3, 2x=3, x= . This number belongs to the set x>1.
Answer: x1=-1.5; x2=1.5.
Example 4. Solve the equation:½x+2½+3½x½=2½x-1½.
Let's show a brief record of the solution of the equation, expanding the sign of the modulus "by intervals".
x £-2, -(x + 2) -3x \u003d -2 (x-1), - 4x \u003d 4, x \u003d -2О (-¥; -2]
–2<х£0, х+2-3х=-2(х-1), 0=0, хÎ(-2; 0]
0<х£1, х+2+3х=-2(х-1), 6х=0, х=0Ï(0; 1]
x>1, x+2+3x=2(x-1), 2x=-4, x=-2W(1; +¥)
Answer: [-2; 0]
Example 5. Solve the equation: (a-1) (a + 1) x \u003d (a-1) (a + 2), for all values of the parameter a.
This equation actually has two variables, but considers x to be the unknown and a to be the parameter. It is required to solve the equation with respect to the variable x for any value of the parameter a.
If a=1, then the equation has the form 0×x=0, any number satisfies this equation.
If a \u003d -1, then the equation has the form 0 × x \u003d -2, this equation does not satisfy any number.
If a¹1, a¹-1, then the equation has a unique solution.
Answer: if a=1, then x is any number;
if a=-1, then there are no solutions;
if a¹±1, then .
B) Linear inequalities with one variable.
If the variable x is given a numerical value, then we get numerical inequality expressing either a true or false statement. Let, for example, the inequality 5x-1>3x+2 be given. With x=2 we get 5 2-1> 3 2+2 - true statement (true numerical statement); for x=0 we get 5·0-1>3·0+2 – a false statement. Any value of a variable for which a given inequality with a variable turns into a true numerical inequality is called a solution to the inequality. Solving an inequality with a variable means finding the set of all its solutions.
Two inequalities with one variable x are said to be equivalent if the solution sets of these inequalities are the same.
The main idea of solving the inequality is as follows: we replace the given inequality with another one, simpler, but equivalent to the given one; the resulting inequality is again replaced by a simpler equivalent inequality, and so on.
Such replacements are carried out on the basis of the following assertions.
Theorem 1. If any term of the inequality with one variable is transferred from one part of the inequality to another with the opposite sign, while leaving the sign of the inequality unchanged, then an inequality equivalent to the given one will be obtained.
Theorem 2. If both parts of an inequality with one variable are multiplied or divided by the same positive number, leaving the inequality sign unchanged, then we get an inequality equivalent to the given one.
Theorem 3. If both parts of an inequality with one variable are multiplied or divided by the same negative number, while changing the sign of the inequality to the opposite, then an inequality equivalent to the given one will be obtained.
An inequality of the form ax+b>0 (respectively, ax+b<0, ax+b³0, ax+b£0), где а и b – действительные числа, причем а¹0. Решение этих неравенств основано на трех теоремах равносильности изложенных выше.
Example 1. Solve the inequality: 2(x-3) + 5(1-x)³3(2x-5).
Opening the brackets, we get 2x-6 + 5-5x³6x-15,