Equations reduced to quadratic. Equations reducible to quadratic equations Quadratic equations reducible to quadratic

State budgetary professional educational institution

"Nevinnomyssk Energy College"

Methodological development open class in the discipline "Mathematics"

Lesson topic :

Equations reducing to quadratic

equations.

Mathematics teacher:

Skrylnikova Valentina Evgenievna

Nevinnomyssk 2016.

Lesson objectives: Slide No. 2

Educational: contribute to the organization of students’ activities in perception,

comprehension and primary memorization of new knowledge (method of introducing a new variable, definition biquadratic equation) and methods

actions (teach how to solve equations by introducing a new

variable), help students understand social and personal

importance educational material;

Educational: help improve students' computing ability;

development of oral mathematical speech; create conditions for

formation of self-control and mutual control skills,

algorithmic culture of students;

Educational: promote a positive attitude

to each other.

Lesson type: learning new material.

Methods: verbal, visual, practical, search

Forms of work : individual, pair, group

Equipment: interactive whiteboard, presentation

Progress of the lesson.

I. Organizational moment.

Mark those absent, check the class's readiness for the lesson.

Teacher: Guys, we are starting to study new topic. We are not writing down the topic of the lesson yet; you will formulate it yourself a little later. Let me just say that we will talk about equations.

Slide number 3.

Through equations, theorems

He solved a lot of problems.

And he predicted drought, and heavy rains -

Truly his knowledge is marvelous.

Goser.

You guys have already solved dozens of equations. You can solve problems using equations. Using equations, you can describe various phenomena in nature, physical, chemical phenomena, even population growth in a country is described by an equation.Today in the lesson we will learn another truth, a truth concerning the method of solving equations.

II. Updating knowledge.

But first, let's remember:

Questions: Slide4

What equations are called quadratic? (An equation of the form, whereX – variable, - some numbers, and a≠0.)

Among the given equations, choose those that are quadratic?

1) 4x – 5 = x + 11

2) x 2 +2x = 3

3) 2x + 6x 2 = 0

4) 2x 3 - X 2 – 4 = 8

5) 4x 2 – 1x + 7 = 0 Answer: (2,3,5)

What equations are called incomplete quadratic equations?(Equations in which at least one of the coefficientsV orWith equals 0.)

Among the given equations, select those that are incomplete quadratic equations.(3)

Test forecast

1) 3x-5x 2 +2=0

2) 2x 2 +4x-6=0

3) 8x 2 -16=0

4) x 2 -4x+10=0

5) 4x 2 +2x=0

6) –2x 2 +2=0

7) -7x 2 =0

8) 15-4x 2 +3x=0

1 option

1) Write down the numbers of complete quadratic equations.

2) Write down the coefficients a, b, c in equation 8.

3) Write down the number of an incomplete quadratic equation that has one root.

4) Write down the coefficients a, b, c in equation 6.

5) Find D in equation 4 and draw a conclusion about the number of roots.

Option 2

1) Write down the numbers of incomplete quadratic equations.

2) Write down the coefficients a, b, c in equation 1.

3) Write down the number of an incomplete quadratic equation that has one root 0.

4) Write down the coefficients a, b, c in equation 3.

5) Find D in equation 3 and draw a conclusion about the number of roots.

Students exchange notebooks, perform mutual testing and give grades.

1st century

1,2,4,8

a=-4, b=3, c=15

a=-2, b=0, c=2

24, D<0, корней нет

2c.

3,5,6,7

a=-5, b=3, c=2

a=8, b=0, c=-16

D>0, 2 roots.

Game "Guess the word."

And now you must guess the word that is written on the board. To do this, you need to solve equations and find the correct answers for them. Each answer corresponds to a letter, and each letter corresponds to a card number and a number in the table to which this letter corresponds. The board shows table No. 1 in its entirety and table No. 2, in which only numbers are written; the teacher writes in the letters as the examples are solved. The teacher distributes cards with quadratic equations to each student. Each card is numbered. A student solves a quadratic equation and gets the answer -21. In the table he finds his answer and finds out which letter corresponds to his answer. This is the letter A. Then he tells the teacher what letter it is and gives the card number. The card number corresponds to the place of the letter in table No. 2. For example, the answer is -21 letter A, card number 5. The teacher in table No. 2 under the number 5 writes the letter A, etc. until the expression is completely written.

X 2 -5x+6=0 (2;3) B

X 2 -2x-15=0(-3;5) AND

X 2 +6x+8=0(-4;-2) K

X 2 -3x-18=0(-3;6) V

X 2- 42x+441=0-21 A

X 2 +8x+7=0(-7;-1) D

X 2 -34x+289=017 R

X 2 -42x+441=0 -21 A

X 2 +4x-5=0(-5;1) T

2x 2 +3x+1=0(-1;-) N

3x 2 -3x+4=0No roots O

5x 2 -8x+3=0 (;1) E

X 2 -8x+15=0(3;5) U

X 2 -34x+289=017 R

X 2 -42x+441=0-21 A

X 2 -3x-18=0(-3;6) V

2x 2 +3x+1=0(-1;-) N

5x 2 -8x+3=0 (;1) E

2x 2 +3x+1=0(-1;-) N

X 2 -2x-15=0(-3;5) AND

5x 2 -8x+3=0(;1) E

Table 1.

(;1)

(-3;5)

(-4;-2)

(-1;-)

no roots

(-5;1)

(3;5)

Its corresponding letter

Table 2

So, we formulated the topic of today’s lesson in this way.

"Biquadratic equation."

III. Learning new material

You already know how to solve quadratic equations various types. Today in the lesson we move on to the consideration of equations leading to the solution of quadratic equations. One such type of equation isbiquadratic equation.

Def. Equations viewax 4 +bx 2 +c= 0 , WhereA 0, calledbiquadratic equation .

BIQUADRATE EQUATIONS – frombi – two andLatinquadratus – square, i.e. twice square.

Example 1. Let's solve the equation

Solution. The solution of biquadratic equations is reduced to the solution of quadratic equations by substitutiony = x 2 .

To findX back to replacement:

x 1 = 1; x 2 = -1 x 3 =; x 4 = - Answer: -1; -1

From the example considered, it is clear that to reduce the equation of the fourth degree to a quadratic one, another variable was introduced -at . This method of solving equations is calledby introducing new variables.

To solve equations that lead to solving quadratic equations by introducing a new variable, you can create the following algorithm:

1) Introduce a change of variable: letX 2 = y

2) Create a quadratic equation with a new variable:aw 2 + wu + c = 0

3) Solve a new quadratic equation

4) Return to variable replacement

5) Solve the resulting quadratic equations

6) Draw a conclusion about the number of solutions to the biquadratic equation

7) Write down the answer

Solving not only biquadratic, but also some other types of equations comes down to solving quadratic equations.

Example 2. Let's solve the equation

Solution. Let's introduce a new variable

no roots.

no roots

Answer: -

IV. Primary consolidation

You and I learned how to introduce a new variable, you are tired, so let’s rest a little.

Fizminutka

1. Close your eyes. Open your eyes (5 times).

2. Circular movements with the eyes. Do not rotate your head (10 times).

3. Without turning your head, look as far to the left as possible. Don't blink. Look straight ahead. Blink a few times. Close your eyes and relax. The same to the right (2-3 times).

4. Look at any object in front of you and turn your head to the right and left without taking your eyes off this object (2-3 times).

5. Look out the window into the distance for 1 minute.

6. Blink for 10-15 seconds.

Relax by closing your eyes.

So we opened new method solving equations, however, the success of solving equations using this method depends on the correctness of composing the equation with a new variable, let's look at this stage of solving equations in more detail. Let's learn how to introduce a new variable and create a new equation, card number 1

Each student has a card

CARD No. 1

Write down the equation obtained by introducing a new variable

X 4 -13x 2 +36=0

let y= ,

Then

X 4 +3x 2 -28 = 0

let y=

Then

(3x–5) 2 – 4(3x–5)=12

let y=

Then

(6x+1) 2 +2(6x+1) –24=0

let y=

Then

X 4 – 25x 2 + 144 = 0

let y=

Then

16x 4 – 8x 2 + 1 = 0

let y=

Then

Knowledge test:

X 4 -13x 2 +36=0

let y=x 2 ,

then have 2 -13у+36=0

X 4 +3x 2 -28 = 0

let y=x 2 ,

then have 2 +3у-28=0

(3x–5) 2 – 4(3x–5)=12

let y=3x-5,

then have 2 -4у-12=0

(6x+1) 2 +2(6x+1) –24=0

let y=6x+1,

then have 2 +2у-24=0

X 4 – 25x 2 + 144 = 0

let y=x 2 ,

then have 2 -25у+144=0

16x 4 – 8x 2 + 1 = 0

let y=x 2 ,

then 16u 2 -8у+1=0

Solving examples at the board:

Independent work:

Option 1 Option 2

1)x 4 -5x 2 -36=0 1) x 4 -6x 2 +8=0

2)(2x 2 +3) 2 -12(2x 2 +3)+11=0 2) (x 2 +3) 2 -11(x 2 +3)+28=0

Answers:

Option 1 Option 2

1) -3;3 1) -;-2;2

2) -2;2 2) -1;1;-2;2.

V. Lesson summary

To summarize the lesson and draw conclusions about what worked or failed, I ask you to complete the sentences on the sheets.

- It was interesting because...

- I would like to praise myself for...

- I would rate the lesson at...

VI. Homework :

(2x 2 +x-1)(2x 2 +x-4)+2=0

(X 2 -4x) 2 +9(x 2 -4х)+20=0

(X 2 +x)(x 2 +x-5)=84

MUNICIPAL EDUCATIONAL INSTITUTION TUMANOVSKAYA SECONDARY SCHOOL OF MOSKALENSKY MUNICIPAL DISTRICT OF OMSK REGION

Lesson topic: EQUATIONS REDUCABLE TO SQUARE

Developed by teacher of mathematics and physics at Tumanovskaya secondary school BIRIKH TATYANA VIKTOROVNA

2008

Purpose of the lesson: 1) consider ways to solve equations reducible to quadratic ones; teach how to solve such equations. 2) develop students’ speech and thinking, attentiveness, and logical thinking. 3) instill an interest in mathematics,

Lesson type: Lesson on learning new material

Lesson plan: 1. organizational stage
2. oral work
3. practical work
4. summing up the lesson

PROGRESS OF THE LESSON
Today in the lesson we will get acquainted with the topic “Equations reducible to quadratic”. Each student must be able to correctly and rationally solve equations, learn to apply various ways when solving the given quadratic equations.
1. Oral work 1. Which of the numbers: -3, -2, -1, 0, 1, 2, 3 are the roots of the equation: a) x 3 – x = 0; b) y 3 – 9y = 0; c) y 3 + 4y = 0? - How many solutions can a third-degree equation have? - What method did you use to solve these equations?2. Check the solution to the equation: x 3 - 3x 2 + 4x – 12 = 0 x 2 (x - 3) + 4 (x - 3) = 0(x - 3) (x 2 + 4) = 0 (x - 3) (x - 2) (x + 2) = 0 Answer: x = 3, x = -2, x = 2 Students explain the mistake they made. I summarize the oral work. So, you were able to solve the three proposed equations orally and find the mistake made when solving the fourth equation. At oral decision equations, the following two methods were used: placing the common factor outside the bracket sign and factoring. Now let's try to apply these methods when doing written work.
2. Practical work 1. One student solves the equation on the board 25x 3 – 50x 2 – x + 2 = 0 When solving, he pays special attention to the change of signs in the second bracket. He recites the entire solution and finds the roots of the equation.2. I suggest that stronger students solve the equation x 3 – x 2 – 4(x - 1) 2 = 0. When checking a solution, I draw students’ special attention to the most important points.3. Work on the board. Solve the equation (x 2 + 2x) 2 – 2(x 2 + 2x) – 3 = 0 When solving this equation, students find out that it is necessary to use a “new” method - introducing a new variable.Let us denote by the variable y = x 2 + 2x and substitute it into this equation. y 2 – 2y – 3 = 0. Let's solve the quadratic equation for the variable y. Then we find the value of the variable x.4 . Consider the equation (x 2 – x + 1) (x 2 – x - 7) = 65. Let's answer the questions:- what degree is this equation?- what solution method is most rational to use to solve it?- what new variable should be introduced? (x 2 – x + 1) (x 2 – x - 7) = 65 Let's denote y = x 2 – x (y + 1) (y – 7) = 65Next, the class solves the equation independently. We check the solutions to the equation at the board.5. For strong students, I suggest solving the equation x 6 – 3x 4 – x 2 – 3 = 0 Answer: -1, 1 6. The equation (2x 2 + 7x - 8) (2x 2 + 7x - 3) – 6 = 0 class proposes to solve as follows: the strongest students - solve independently; for the rest, one of the students on the board decides.Solve: 2x 2 + 7x = y(y - 8) (y - 3) – 6 = 0 We find: y1 = 2, y2 = 9 Substitute into our equation and find the values of x, for this we solve the equations:2x 2 + 7x = 2 2x 2 + 7x = 9As a result of solving two equations, we find four values of x, which are the roots of this equation.7. At the end of the lesson, I propose to solve the equation x 6 – 1 = 0 orally. When solving it is necessary to apply the difference of squares formula; we can easily find the roots.(x 3) 2 – 1 = 0 (x 3 - 1) (x 3 + 1) = 0 Answer: -1, 1.
3. Summing up the lesson Once again I draw the students’ attention to the methods that were used to solve equations reduced to quadratic equations. Students’ work in class is evaluated, I comment on the grades and point out mistakes made. We write down our homework. As a rule, the lesson proceeds at a fast pace, and the students’ performance is high. Thank you all very much for the good work.

There are several classes of equations that can be solved by reducing them to quadratic equations. One of these equations is biquadratic equations.

Biquadratic equations

Biquadratic equations are equations of the form a*x^4 + b*x^2 + c = 0, where a is not equal to 0.

Biquadratic equations are solved using the substitution x^2 =t. After such a substitution, we obtain a quadratic equation for t. a*t^2+b*t+c=0. We solve the resulting equation, and in the general case we have t1 and t2. If at this stage a negative root is obtained, it can be excluded from the solution, since we took t=x^2, and the square of any number is a positive number.

Returning to the original variables, we have x^2 =t1, x^2=t2.

x1,2 = ±√(t1), x3,4=±√(t2).

Let's look at a small example:

9*x^4+5*x^2 - 4 = 0.

Let's introduce the replacement t=x^2. Then the original equation will take the following form:

9*t^2+5*t-4=0.

We solve this quadratic equation using any of the known methods and find:

t1=4/9, t2=-1.

The root -1 is not suitable, since the equation x^2 = -1 does not make sense.

The second root 4/9 remains. Moving on to the initial variables, we have the following equation:

x^2 = 4/9.

x1=-2/3, x2=2/3.

This will be the solution to the equation.

Answer: x1=-2/3, x2=2/3.

Another type of equation that can be reduced to quadratic equations is fractional rational equations. Rational equations are equations whose left and right sides are rational expressions. If in a rational equation the left or right sides are fractional expressions, then such a rational equation is called fractional.

Scheme for solving a fractional rational equation

General scheme for solving a fractional rational equation.

1. Find common denominator all the fractions that go into the equation.

2. Multiply both sides of the equation by a common denominator.

3. Solve the resulting whole equation.

4. Check the roots and exclude those that make the common denominator vanish.

Let's look at an example:

Solve the fractional rational equation: (x-3)/(x-5) + 1/x = (x+5)/(x*(x-5)).

We will stick to general scheme. Let's first find the common denominator of all fractions.

We get x*(x-5).

Multiply each fraction by a common denominator and write the resulting whole equation.

x*(x+3) + (x-5) = (x+5);

Let us simplify the resulting equation. We get,

x^2+3*x + x-5 - x - 5 =0;

x^2+3*x-10=0;

Received simple reduced quadratic equation. We solve it by any of the known methods, we get the roots x=-2 and x=5. Now we check the obtained solutions. Substitute the numbers -2 and 5 into the common denominator.

At x=-2, the common denominator x*(x-5) does not vanish, -2*(-2-5)=14. This means that the number -2 will be the root of the original fractional rational equation.

At x=5 the common denominator x*(x-5) becomes zero. Therefore, this number is not the root of the original fractional rational equation, since there will be a division by zero.

Answer: x=-2.

Quadratic equation or an equation of the second degree with one unknown is an equation that, after transformations, can be reduced to the following form:

ax 2 + bx + c = 0 - quadratic equation

Where x- this is the unknown, but a, b And c- coefficients of the equation. In quadratic equations a called the first coefficient ( a ≠ 0), b is called the second coefficient, and c called a known or free member.

Equation:

ax 2 + bx + c = 0

called complete quadratic equation. If one of the coefficients b or c is equal to zero, or both of these coefficients are equal to zero, then the equation is presented in the form of an incomplete quadratic equation.

Reduced quadratic equation

The complete quadratic equation can be reduced to a more convenient form by dividing all its terms by a, that is, for the first coefficient:

Equation x 2 + px + q= 0 is called a reduced quadratic equation. Therefore, any quadratic equation in which the first coefficient is equal to 1 can be called reduced.

For example, the equation:

x 2 + 10x - 5 = 0

is reduced, and the equation:

3x 2 + 9x - 12 = 0

can be replaced by the above equation, dividing all its terms by -3:

x 2 - 3x + 4 = 0

Solving Quadratic Equations

To solve a quadratic equation, you need to reduce it to one of the following forms:

ax 2 + bx + c = 0

ax 2 + 2kx + c = 0

x 2 + px + q = 0

For each type of equation there is its own formula for finding roots:

Notice the equation:

ax 2 + 2kx + c = 0

this is the transformed equation ax 2 + bx + c= 0, in which the coefficient b- even, which allows you to replace it with type 2 k. Therefore, the formula for finding the roots for this equation can be simplified by substituting 2 into it k instead of b:

Example 1. Solve the equation:

3x 2 + 7x + 2 = 0

Since the second coefficient in the equation is not an even number, and the first coefficient is not equal to one, we will look for roots using the very first formula, called general formula finding the roots of a quadratic equation. At first

a = 3, b = 7, c = 2

Now, to find the roots of the equation, we simply substitute the values of the coefficients into the formula:

x 1 =	-2	= -	1	, x 2 =	-12	= -2
	6		3		6

Answer: -	1	, -2.
	3

Example 2:

x 2 - 4x - 60 = 0

Let's determine what the coefficients are:

a = 1, b = -4, c = -60

Since the second coefficient in the equation is an even number, we will use the formula for quadratic equations with an even second coefficient:

x 1 = 2 + 8 = 10, x 2 = 2 - 8 = -6

Answer: 10, -6.

Example 3.

y 2 + 11y = y - 25

Let's reduce the equation to general appearance:

y 2 + 11y = y - 25

y 2 + 11y - y + 25 = 0

y 2 + 10y + 25 = 0

Let's determine what the coefficients are:

a = 1, p = 10, q = 25

Since the first coefficient is equal to 1, we will look for roots using the formula for the above equations with an even second coefficient:

Answer: -5.

Example 4.

x 2 - 7x + 6 = 0

Let's determine what the coefficients are:

a = 1, p = -7, q = 6

Since the first coefficient is equal to 1, we will look for roots using the formula for the above equations with an odd second coefficient:

x 1 = (7 + 5) : 2 = 6, x 2 = (7 - 5) : 2 = 1

Lesson #1

Lesson type: lesson of learning new material.

Lesson format: conversation.

Target: develop the ability to solve equations reduced to quadratic ones.

Tasks:

introduce students to one of the ways to solve equations;
develop skills in solving such equations;
create conditions for the formation of interest in the subject and the development of logical thinking;
to ensure personal and humane relationships between participants in the educational process.

Lesson plan:

1. Organizational moment.

3. Studying new material.
4. Consolidation of new material.
5. Homework.
6. Lesson summary.

PROGRESS OF THE LESSON

1. Organizational moment

Teacher:“Guys, today we begin to study the important and interesting topic"Equations Reducible to Quadratic Equations." You know the concept of a quadratic equation. Let's remember what we know on this topic."

Schoolchildren are given instructions:

Remember the definitions associated with this topic.
Remember the methods for solving known equations.
Remember your difficulties when completing tasks on topics that are “close” to this one.
Remember ways to overcome difficulties.
Think through possible research tasks and ways to complete them.
Remember where previously solved problems were applied.

Students recall the form of a complete quadratic equation, an incomplete quadratic equation, conditions for solving a complete quadratic equation, methods for solving incomplete quadratic equations, the concept of a whole equation, the concept of a degree.

The teacher suggests solving the following equations (work in pairs):

a) x 2 – 10x + 21 = 0
b) 3x 2 + 6x + 8 = 0
c) x (x – 1) + x 2 (x – 1) = 0

One of the students comments on the solution to these equations.

3. Learning new material

The teacher suggests considering and solving the following equation (problem problem):

(x 2 – 5x + 4) (x 2 – 5x + 6) = 120

Students talk about the power of a given equation and suggest multiplying these factors. But there are students who notice the same terms in this equation. What solution method can be applied here?
The teacher invites the students to turn to the textbook (Yu. N. Makarychev “Algebra-9”, paragraph 11, p. 63) and figure out the solution to this equation. The class is divided into two groups. Those students who understand the solution method perform the following tasks:

a) (x 2 + 2x) (x 2 +2x + 2) = –1
b) (x 2 – 7) 2 – 4 (x 2 – 7) – 45 = 0,

the rest are solution algorithm such equations and analyze the solution to the next equation together with the teacher.

(2x 2 + 3) 2 – 12(2x 2 + 3) + 11 = 0.

Algorithm:

– enter a new variable;
– create an equation containing this variable;
– solve the equation;
– substitute the found roots into the substitution;
– solve the equation with the initial variable;
– check the roots found, write down the answer.

4. Consolidation of new material

Work in pairs: “strong” explains, “weak” repeats, decides.

Solve the equation:

a) 9x 3 – 27x 2 = 0
b) x 4 – 13x 2 + 36 = 0

Teacher:“Let's remember where else we used solving quadratic equations?”

Students:“When solving inequalities; when finding the domain of definition of a function; when solving equations with a parameter.”
The teacher offers optional assignments. The class is divided into 4 groups. Each group explains the solution to their task.

a) Solve the equation:
b) Find the domain of definition of the function:
c) At what values A the equation has no roots:
d) Solve the equation: x + – 20 = 0.

5. Homework

No. 221(a, b, c), No. 222(a, b, c).

The teacher suggests preparing messages:

1. " Historical information on the creation of these equations" (based on materials from the Internet).
2. Methods for solving equations on the pages of the Kvant magazine.

Quests creative nature Perform as desired in separate notebooks:

a) x 6 + 2x 4 – 3x 2 = 0
b) (x 2 + x) / (x 2 + x – 2) – (x 2 + x – 5) / (x 2 + x – 4) = 1

6. Lesson summary

The guys tell us what they learned new in the lesson, what tasks caused difficulties, where they applied them, and how they evaluate their performance.

Lesson #2

Lesson type: lesson on consolidating skills and abilities.

Lesson format: lesson workshop.

Target: consolidate acquired knowledge, develop the ability to solve equations on this topic.

Tasks:

develop the ability to solve equations reduced to quadratic ones;
develop independent thinking skills;
develop the ability to conduct analysis and search for missing information;
cultivate activity, independence, discipline.

Lesson plan:

1. Organizational moment.
2. Updating the subjective experience of students.
3. Problem solving.
4. Independent work.
5. Homework.
6. Lesson summary.

PROGRESS OF THE LESSON

1. Organizational moment

Teacher:“In the last lesson we learned about equations that can be reduced to quadratic equations. Which mathematician contributed to the solution of equations of the third and fourth degrees?”

The student who prepared the message talks about Italian mathematicians of the 16th century.

2. Actualization of subjective experience

1) Checking homework

A student is called to the board and solves equations similar to home ones:

a) (x 2 – 10) 2 – 3 (x 2 – 10) – 4 = 0
b) x 4 – 10 x 2 + 9 = 0

At this time, to bridge gaps in knowledge, “weak” students receive cards. The “weak” student comments the solution to the “strong” student, the “strong” student marks the solution with “+” or “–” signs.

2) Repetition of theoretical material

Students are asked to fill out a table like:

Students fill out the third column at the end of the lesson.
The task completed on the board is checked. A sample solution remains on the board.

3. Problem solving

The teacher offers a choice of two groups of equations. The class is divided into two groups. One performs tasks according to the model, the other looks for new methods for solving equations. If decisions cause difficulties, then students can turn to a model - reasoning.

a) (2x 2 + 3) 2 – 12 (2x 2 + 3) + 11 = 0 a) (5x – 63) (5 x – 18) = 550
b) x 4 – 4x 2 + 4 = 0 b) 2x 3 – 7 x 2 + 9 = 0

The first group comments on their solution, the second group checks the solution through an overhead projector and comments on their solution methods.

Teacher: Guys, let's look at one interesting equation: (x 2 – 6 x – 9) 2 = x (x 2 – 4 x – 9).

– What method do you propose to solve it?

Students begin to discuss the problem problem in groups. They propose to open the brackets, bring similar terms, obtain a whole algebraic equation of the fourth degree, and find whole roots, if any, among the divisors of the free term; then factorize and find the roots of this equation.
The teacher approves the solution algorithm and suggests considering another solution method.

Let us denote x 2 – 4x – 9 = t, then x 2 – 6x – 9 = t – 2x. We obtain the equation t 2 – 5tx + 4x 2 = 0 and solve it for t.

The original equation breaks down into a set of two equations:

x 2 – 4 x – 9 = 4x x = – 1
x 2 – 4 x – 9 = x x = 9
x = (5 + 61)/2 x = (5 – 61)/2

4. Independent work

Students are offered the following equations to choose from:

a) x 4 – 6 x 2 + 5 = 0 a) (1 – y 2) + 7 (1 – y 2) + 12 = 0
b) (x 2 + x) 2 – 8 (x 2 + x) + 12 = 0 b) x 4 + 4 x 2 – 18 x 2 – 12 x + 9 = 0
c) x 6 + 27 x 4 – 28 = 0

The teacher comments on the equations of each group, drawing attention to the fact that the equation under point c) allows students to deepen their knowledge and skills.
Independent work is done on paper using carbon paper.
Students check solutions through an overhead projector after exchanging notebooks.

5. Homework

No. 223(g, e, f), No. 224(a, b) or No. 225, No. 226.

Creative task.

Determine the degree of the equation and derive the Vieta formula for this equation:

6. Lesson summary

Students return to filling out the “I learned” column of the table.

Lesson #3

Lesson type: lesson of review and systematization of knowledge.

Lesson format: lesson is a competition.

Objective of the lesson: learn to correctly evaluate your knowledge and skills, correctly correlate your capabilities with the tasks offered.

Tasks:

teach you how to apply your knowledge comprehensively;
identify the depth and strength of skills and abilities;
promote rational organization of labor;
foster activity and independence.

Lesson plan:

1. Organizational moment.
2. Updating the subjective experience of students.
3. Problem solving.
4. Independent work.
5. Homework.
6. Lesson summary.

PROGRESS OF THE LESSON

1. Organizational moment

Teacher:“Today we will conduct an unusual lesson, a competition lesson. You are already familiar with the Italian mathematicians Fiori, N. Tartaglia, L. Ferrari, D. Cardano from the last lesson.

On February 12, 1535, a scientific duel took place between Fiori and N. Tartaglia, in which Tartaglia won a brilliant victory. In two hours he solved all thirty problems proposed by Fiori, while Fiori did not solve a single problem of Tartaglia.
How many equations can you solve in a lesson? What methods should you choose? Italian mathematicians offer you their equations.”

2. Actualization of subjective experience

Oral work

1) Which of the numbers: – 3, – 2, – 1, 0, 1, 2, 3 are the roots of the equation:

a) x 3 – x = 0 b) y 3 – 9 y = 0 c) y 3 + 4 y = 0?

– How many solutions can a third-degree equation have?
– What method will you use to solve these equations?

2) Check the solution to the equation. Find the mistake you made.

x 3 – 3x 2 + 4x – 12 = 0
x 2 (x – 3) + 4 (x – 3) = 0
(x – 3)(x 2 + 4) = 0
(x – 3)(x + 2)(x – 2) = 0
x = 3, x = – 2, x = 2.

Work in pairs. Students explain how to solve equations and the mistake they made.

Teacher:“You guys are great! You have completed the first task of Italian mathematicians.”

3. Problem solving

Two students at the blackboard:

a) Find the coordinates of the points of intersection with the coordinate axes of the graph of the function:

b) Solve the equation:

Students in the class choose to complete one or two tasks. Students at the board consistently comment on their actions.

4. “End-to-end” independent work

The set of cards is compiled according to difficulty level and with answer options.

1) x 4 – x 2 – 12 = 0
2) 16 x 3 – 32 x 2 – x + 2 = 0
3) (x 2 + 2 x) 2 – 7 (x 2 + 2 x) – 8 = 0
4) (x 2 + 3 x + 1) (x 2 + 3 x + 3) = – 1
5) x 4 + x 3 – 4 x 2 + x + 1 = 0

Possible answers:

1) a) – 2; 2 b) – 3; 3 c) no solution
2) a) – 1/4; 1/4 b) – 1/4; 1/4; 2 c) 1/4; 2
3) a) – 4; 1; 2 b) –1; 1; – 4; 2 c) – 4; 2
4) a) – 2; – 1; b) – 2; – 1; 1 c) 1; 2
5) a) – 1; (– 3 + 5) /2 b) 1; (– 3 – 5) /2 c) 1; (– 3 – 5)/2; (–3 + 5) /2.

5. Homework

Collection of tasks for a written exam in algebra: No. 72, No. 73 or No. 76, No. 78.

Additional task. Determine the value of the parameter a for which the equation x 4 + (a 2 – a + 1) x 2 – a 3 – a = 0