Equations

An equation is a mathematical statement that has two expressions separated by an equal sign. Solving an equation means manipulating the expressions and finding the value of the variables.

An equation in one variable has a single unknown quantity called a variable represented by a letter. Eg: ‘x’, where ‘x’ is always to the power of 1. This means there is no ‘ x² ’ or ‘ x³ ’ in the equation.

5x + 2 = 2x + 17
Subtract 2x from both sides:
5x + 2 - 2x = 2x + 17 - 2x
Simplify both sides:
3x + 2 = 17
Subtract 2 from both sides:
3x + 2 - 2 = 17 - 2
Simplify both sides:
3x = 15
Divide both sides by 3:
Simplify both sides:
x = 5

Zero Product

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

Use the principle of zero product, which says, if ab = 0 , either a, b, or both must be equal to zero.

3x - 2 = 0 0x + 1 = 0
3x = 2 x = -1
x = (2/3)



The solutions are : -1 and 2/3

Quadratic equation

A general quadratic equation can be written in the form, where x represents a variable or an unknown and a, b, and c are constants with a ≠ 0. (If a = 0, the equation is a linear equation .)

Polynomial equation solved by factoring :

3 − 11/2 x − 5x² = 0
5x² +11/2 x − 3= 0
5x² +11/2 x− 3 = 0
(5x − 2 )(2x + 3)= 0
So , the solutions are 2/5and −3/2

Solved by completing the square

Completing the square is a technique for converting a quadratic polynomial of the form

Ax^2+bx+c to a(x-h)^2+k

3x²+12x+27 = 3(x²+4x+9 )
= 3((x+2)²+5)
=3(x+2)²+5

By Parameswari & Sivapriya 2nde 2 =)

Emma and Me have presented the theorem of thales.
So Here it is.
Thales Miletus was the innovator of the theorem, a great greek philosopher and mathimatician too.
He was born around 624BC and died in 546BC.
He discovered many thing like the five theorems.
Even though, eguptians and babylonians were the first to discover this theorem, it took the name of the one who prooved it : Thales.
It's a particular case of the intercept theorems.
So, Thales' theorem says : if A, B and C are points on a circle where the line AC is a diameter of the circle, then the angle ABC is a right angle.

The Theorem of Pythagoras

Who is Pythagoras? What is this this theorem about?

Pythagoras of Samos was a Greek philosopher who lived around 530 BC, mostly in the Greek colony of Crotona in southern Italy. According to tradition he was the first to prove the assertion (theorem) which today bears his name:

If a triangle has sides of length (a,b,c), with sides (a,b) enclosing an angle of 90 degrees ("right angle"), then

a2 + b2 = c2

A right angle can be defined here as the angle formed when two straight lines cross each other in such a way that all 4 angles produced are equal. The theorem also works the other way around and that is called the reciprocal of the Pythagorean theorem: if the lengths of the three sides (a,b,c) of a triangle satisfy the above relation, then the angle between sides a and b must be of 90 degrees.

Examples of both of the theorem

FIND LM:

In the triangle LNM right angled in N we have for after the Pythagorean theorem:

LM² = LN² +NM²

LM2 =4² +3² =25

LM=√25=5

So we can conclude that that LM is equal to 5.

SHOW THAT THIS TRIANGLE IS RIGHT ANGLED:

BC² =13²=169

AB²+BC²=5²+12²=169

As BC2=AB2+BC2, for after the reciprocal of the Pythagorean theorem, the triangle ABC is right angled in A.

Proof of the Pythagorean theorem:

Bhaskara's first Proof of the Pythagorean Theorem:

Bhaskara was born in India. He was one of the most important Hindu mathematicians of the second century AD.

He used the following diagrams in proving the Pythagorean Theorem In the above diagrams, the blue triangals are all congruent and the yellow squares are congruent. First we need to find the area of the big square two different ways. First let's find the area using the area formula for a square.
Thus, A=c^2.
Now, lets find the area by finding the area of each of the components and then sum the areas.
Area of the blue triangles = 4(1/2)ab
Area of the yellow square = (b-a)^2
Area of the big square = 4(1/2)ab + (b-a)^2
= 2ab + b^2 - 2ab + a^2
= b^2 + a^2
Since, the square has the same area no matter how you find it
A = c^2 = a^2 + b^2.

By Vicnèche and Karan