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Other calculators
- Square Inequality Step-by-Step
- Inequality with the module Step by Step
- Logarithmic inequality online
-
How to use it?
- Inequation:
- 2x²+6x>=0
-
8x^2-72x+144>0
- log7(4x+11)-log7(25-x^2)>=sin11pi/2
- (4^x-2^x+3)+28(4^x-2^x+3)+192>=0
- Canonical form:
- =0
-
Identical expressions
- 2x²+6x>= zero
- 2x² plus 6x greater than or equal to 0
- 2x² plus 6x greater than or equal to zero
- 2x²+6x>=O
-
Similar expressions
- log(0.2)(x²+6x+8)>log(0.2)(5x+10)
- 2x²-6x>=0
2x²+6x>=0 inequation
The solution
Detail solution
Given the inequality:
$$2 x^{2} + 6 x \geq 0$$
To solve this inequality, we must first solve the corresponding equation:
$$2 x^{2} + 6 x = 0$$
Solve:
This equation is of the form
A quadratic equation can be solved
using the discriminant.
The roots of the quadratic equation:
$$x_{1} = \frac{\sqrt{D} - b}{2 a}$$
$$x_{2} = \frac{- \sqrt{D} - b}{2 a}$$
where D = b^2 - 4*a*c - it is the discriminant.
Because
$$a = 2$$
$$b = 6$$
$$c = 0$$
, then
Because D > 0, then the equation has two roots.
or
$$x_{1} = 0$$
$$x_{2} = -3$$
$$x_{1} = 0$$
$$x_{2} = -3$$
$$x_{1} = 0$$
$$x_{2} = -3$$
This roots
$$x_{2} = -3$$
$$x_{1} = 0$$
is the points with change the sign of the inequality expression.
First define with the sign to the leftmost point:
$$x_{0} \leq x_{2}$$
For example, let's take the point
$$x_{0} = x_{2} - \frac{1}{10}$$
=
$$-3 + - \frac{1}{10}$$
=
$$- \frac{31}{10}$$
substitute to the expression
$$2 x^{2} + 6 x \geq 0$$
$$\frac{\left(-31\right) 6}{10} + 2 \left(- \frac{31}{10}\right)^{2} \geq 0$$
one of the solutions of our inequality is:
$$x \leq -3$$
Other solutions will get with the changeover to the next point
etc.
The answer:
$$x \leq -3$$
$$x \geq 0$$
$$2 x^{2} + 6 x \geq 0$$
To solve this inequality, we must first solve the corresponding equation:
$$2 x^{2} + 6 x = 0$$
Solve:
This equation is of the form
a*x^2 + b*x + c = 0
A quadratic equation can be solved
using the discriminant.
The roots of the quadratic equation:
$$x_{1} = \frac{\sqrt{D} - b}{2 a}$$
$$x_{2} = \frac{- \sqrt{D} - b}{2 a}$$
where D = b^2 - 4*a*c - it is the discriminant.
Because
$$a = 2$$
$$b = 6$$
$$c = 0$$
, then
D = b^2 - 4 * a * c =
(6)^2 - 4 * (2) * (0) = 36
Because D > 0, then the equation has two roots.
x1 = (-b + sqrt(D)) / (2*a)
x2 = (-b - sqrt(D)) / (2*a)
or
$$x_{1} = 0$$
$$x_{2} = -3$$
$$x_{1} = 0$$
$$x_{2} = -3$$
$$x_{1} = 0$$
$$x_{2} = -3$$
This roots
$$x_{2} = -3$$
$$x_{1} = 0$$
is the points with change the sign of the inequality expression.
First define with the sign to the leftmost point:
$$x_{0} \leq x_{2}$$
For example, let's take the point
$$x_{0} = x_{2} - \frac{1}{10}$$
=
$$-3 + - \frac{1}{10}$$
=
$$- \frac{31}{10}$$
substitute to the expression
$$2 x^{2} + 6 x \geq 0$$
$$\frac{\left(-31\right) 6}{10} + 2 \left(- \frac{31}{10}\right)^{2} \geq 0$$
31 -- >= 0 50
one of the solutions of our inequality is:
$$x \leq -3$$
_____ _____
\ /
-------•-------•-------
x2 x1Other solutions will get with the changeover to the next point
etc.
The answer:
$$x \leq -3$$
$$x \geq 0$$
Solving inequality on a graph
Rapid solution 2
[src]
(-oo, -3] U [0, oo)
$$x\ in\ \left(-\infty, -3\right] \cup \left[0, \infty\right)$$
x in Union(Interval(-oo, -3), Interval(0, oo))
Rapid solution
[src]
Or(And(0 <= x, x < oo), And(x <= -3, -oo < x))
$$\left(0 \leq x \wedge x < \infty\right) \vee \left(x \leq -3 \wedge -\infty < x\right)$$
((0 <= x)∧(x < oo))∨((x <= -3)∧(-oo < x))