What role of operations that applies when you are solving an equation does not apply when your solving an inequality?"
It means to find all the numbers for which the inequality is true.
f+5 greater than or equal to 31
not always,sometimes you have to solve for x
You only need to reverse the order of the inequality when multiplying or dividing both sides by a negative number. If you multiply or divide by a positive number, the order of the inequality remains the same. This is crucial to maintain the truth of the inequality. Always be cautious about the sign of the number you are using in these operations.
What role of operations that applies when you are solving an equation does not apply when your solving an inequality?"
In solving an inequality you generally use the same methods as for solving an equation. The main difference is that when you multiply or divide each side by a negative, you have to switch the direction of the inequality sign. The solution to an equation is often a single value, but the solution to an inequality is usually an infinite set of numbers, such as x>3.
When you divide both sides by a negative value
When the two sides of the inequality are multiplied or divided by a negative number or term or expression.
When solving an inequality, you must revers the inequality sign when you multiply (or divide) both sides by a negative number.
The difference between them is that when solving an "and" inequality you are comparing two inequalities and when you are solving an "or" inequality you dont compare, you only use one inequality example of "and" . 2<x+3<7 example of "or" . 4<d or m<1
It means to find all the numbers for which the inequality is true.
What is the inherent meaning and justification of cross-multiplication as it applies to solving an inequality
f+5 greater than or equal to 31
It's the same thing as solving an equation, the minor difference is to change the inequality sign when the numbers change signs(i.e negative to positive to negative).
Yes
not always,sometimes you have to solve for x