The way you state it, that is already the solution of some problem; perhaps of an inequality. There is nothing more you need to do, except perhaps graph it, if the problem asks for it.
The way you state it, that is already the solution of some problem; perhaps of an inequality. There is nothing more you need to do, except perhaps graph it, if the problem asks for it.
The way you state it, that is already the solution of some problem; perhaps of an inequality. There is nothing more you need to do, except perhaps graph it, if the problem asks for it.
The way you state it, that is already the solution of some problem; perhaps of an inequality. There is nothing more you need to do, except perhaps graph it, if the problem asks for it.
The way you state it, that is already the solution of some problem; perhaps of an inequality. There is nothing more you need to do, except perhaps graph it, if the problem asks for it.
The answer to this is 2, and 0.
There are an infinite amount of numbers less than -6
The real numbers greater than or equal to -2, represented by {x: x >= -2 }, is a set. A set is simply a group of things, which you can ask if a particular element is in that set. For example, 17.273 is in {x: x >= -2}, but "apple" is not in {x: x >= -2}. In this case, the set {x: x >= -2} contains all the real numbers that are greater than or equal to -2 and nothing else.
Not always. Here are counterexamples: Cases involving 1: 1 x 1 = 1 1 x 3 = 3 Cases involving positive numbers less than 1: 0.5 x 10 = 5 0.5 x 0.5 = 0.25 Note that here we have positive numbers that are less than or equal to 1. When either number is less than 1, the product will not be greater than both numbers. Also, if either number is equal to 1, the product will be equal to the larger of the original numbers. A modified statement is the product P of two positive real numbers x and y such that x, y > 1, is greater than both x and y.
Well "real numbers" are whole numbers greater than or equal to 0. Therefore, they cannot be negative or have decimals. So in this case, the answer would be: 10 <= x < infinity
The answer to this is 2, and 0.
There are an infinite amount of numbers less than -6
x ≥ 6
The real numbers greater than or equal to -2, represented by {x: x >= -2 }, is a set. A set is simply a group of things, which you can ask if a particular element is in that set. For example, 17.273 is in {x: x >= -2}, but "apple" is not in {x: x >= -2}. In this case, the set {x: x >= -2} contains all the real numbers that are greater than or equal to -2 and nothing else.
{x| x ≥ 6} or the interval [6,∞).
Not always. Here are counterexamples: Cases involving 1: 1 x 1 = 1 1 x 3 = 3 Cases involving positive numbers less than 1: 0.5 x 10 = 5 0.5 x 0.5 = 0.25 Note that here we have positive numbers that are less than or equal to 1. When either number is less than 1, the product will not be greater than both numbers. Also, if either number is equal to 1, the product will be equal to the larger of the original numbers. A modified statement is the product P of two positive real numbers x and y such that x, y > 1, is greater than both x and y.
0
Positive numbers are greater than zero and negative numbers are less than zero. They are both collectively referred to as real numbers.
For all the values of x that are less than one and greater than zero.
All real numbers that are greater than or equal to zero
Real numbers are all numbers. So the answer would be -4 and every number after that in the negative direction. So any number that is less than -4. So, -5, -6, and so on.
Well "real numbers" are whole numbers greater than or equal to 0. Therefore, they cannot be negative or have decimals. So in this case, the answer would be: 10 <= x < infinity