The quadratic equation is the equation in which the unknown occurs at most in the power 2.
By simplifying, all quadratic equations can be translated into the general form of a quadratic equation
where the coefficients a, b and c are any real numbers. The coefficient a is called the coefficient of the quadratic term or the leading coefficient, b the coefficient of the linear term and c the constant term.
The coefficient a cannot be equal to 0, because then the equation is no longer quadratic.
Regarding quadratic equations, it should be emphasized at the outset that, unlike linear equations, where we write a constant term on the right, we arrange them consistently so that the right side is equal to 0, and on the left we classify the terms by decreasing powers.
We have given the equation:
We simplify the equation:
Hence, we got the quadratic equation in general form, where:
Given the equation:
Simplify the equation.
Let's simplify the equation:
The quadratic equation has two solutions, which are calculated according to the form:
where D is the discriminant calculated by the form:
For the solution of a quadratic equation we have as many as six different expressions for it: solutions of the quadratic equation or zeros of the quadratic equation or roots of the quadratic equation or zeros of the quadratic function or intersection of the quadratic function with the x-axis or intersection of the quadratic function with the abscissa.
The nature of the solutions of the quadratic equation depends on the discriminant D:
if 
, the equation has two different real solutions.
if 
, the equation has only one repeated real solution.
if is 
, the equation has no real solution.
The equation has two complex solutions (conjugate complex numbers), which we will discuss in the chapter Complex numbers.
Some cases in solving quadratic equations:
We have a quadratic equation:
The coefficients of the quadratic equation are: a = 1, b = -2 and c = -11. Solve the quadratic equation by first calculating the discriminant according to the form:
Let's obtain the discriminant:
The discriminant value is 
. Since the discriminant is greater than 0, we know that the quadratic equation has two different real solutions. We calculate them using the form:
Let's obtain the roots of the equation:
The solutions of the quadratic equation are:
and 
We have a quadratic equation:
The coefficients of the quadratic equation are: a = 1, b = -4 and c = 4. Solve the quadratic equation by first calculating the discriminant according to the form:
Obtaining the discriminant:
The discriminant value is 
. Since the discriminant is equal to 0, we know that the quadratic equation has only one double real solution. It is calculated using the form:
Let's obtain the roots of the equation:
The solutions of the quadratic equation are: 
.
We have a quadratic equation
The coefficients of the quadratic equation are: a = 2, b = -4 and c = 4. Solve the quadratic equation by first calculating the discriminant according to the form:
Let's obtain the discriminant:
The discriminant value is 
. Because the discriminant is negative, the equation has no realistic solutions. The equation has two complex solutions (conjugate complex numbers), which we will learn to calculate in the chapter Complex numbers.
In the previous chapter, we learned that with the help of two forms:
we can solve any quadratic equation. Solutions or roots of some special forms of quadratic equations can also be obtained by simpler and faster procedures with the help of factorisation, so let's take a look at them:
In the case where the linear term b = 0, the general form of the quadratic equation is transformed into:
The solution is derived by first converting the quadratic equation into a zero or factorized form. In a set of real numbers, the equation can be written in zero form only if a and c have opposite signs. How to write an equation in zero form if a and c have the same sign is discussed in the chapter Complex numbers.
Let's obtain thefactorised form:
Solve the first (linear) equation:
Solve the second (linear) equation:
We have the equation:
The solution is derived by first converting the quadratic equation into a zero or factorized form:
Let's write the equation in a factorized form:
Solve the first (linear) equation:
Solve the second (linear) equation:
In the case when the constant term c = 0, the general form of the quadratic equation is transformed into:
The solution is derived by first converting the quadratic equation into a zero or factorized form:
Let's write the equation in a factorized form:
The first equation has already been solved, so we solve the second (linear) equation:
Let's have the equation:
The solution is derived by first converting the quadratic equation into a zero or factorized form.
Let's write the equation in a factorized form:
The first equation has already been solved, so we solve the second (linear) equation:
In the case where the leading term is a = 1, the general form of the quadratic equation is transformed into:
The quadratic trinomial of the form 
is first disassembled on the basis of the same equation, by means of which it is converted into a zero or factorized form:
Factorisation is possible only if q can be written as the product of two factors m and n whose sum is equal to p.
Solve the factorised equation:
Solve the first (linear) equation:
Solve the second (linear) equation:
We have given the equation:
The coefficients are a = 1, p = - 5 and q = 6.
Let's factorise the expression on left hand side:
Factorise the given equation according to the form 
and solve:
Solve the first (linear) equation:
Solve the second (linear) equation:
The general form of the quadratic equation: 
in zero form using the notation:
where are:
a square term coefficient or leading coefficient and
solutions of the quadratic equation, which are calculated according to the form:
where D is the discriminant calculated by the form:
We have two different terms for the zero form: zero form or factorized form. The process is called factorization.
All quadratic equations can be written in zero form using the form for calculating the solutions of the quadratic equation (also the special forms of quadratic equations from the previous chapter).
