When adding numbers with exponents, you can only combine the terms if they have the same base and the same exponent. For example, (2^3 + 2^3) can be simplified to (2 \times 2^3 = 2^4), which equals (16). However, if the bases or exponents differ, you cannot combine them directly; you must leave them as separate terms.
you do not do anything when you add numbers with exponents. you just figure out the answer. it is only if you multiply numbers with exponents, where you add the exponents..
Fractional exponents follow the same rules as integral exponents. Integral exponents are numbers raised to an integer power.
nothing, keep the exponents the same, remember you can only add or subtract when the exponents are the same
You keep them the same if they have different bases
Same.
When multiplying something with exponents, you add it. When dividing something with exponents, you subtract it.
you do not do anything when you add numbers with exponents. you just figure out the answer. it is only if you multiply numbers with exponents, where you add the exponents..
Fractional exponents follow the same rules as integral exponents. Integral exponents are numbers raised to an integer power.
nothing, keep the exponents the same, remember you can only add or subtract when the exponents are the same
In a multiplication problem with exponents, one should not multiple the exponents. Rather, it would be correct to multiply the numbers while adding the exponents together.
You keep them the same if they have different bases
When adding variables with exponents, you do neither. You only add the exponents if #1 The variables are the same character (such as they are both "a") #2 You are multiplying the variables (NOT ADDING, SUBTRACTING, OR DIVIDING) Using a simple concrete case may make this clearer: 10+2 times 10+3 equals 10+5 ( 100 times 1000 equals 100,000).
Same.
Exactly that ... negative exponents. For example: 1000 = 103 That is a positive exponent. .001 = 10-3 That is a negative exponent. For positive exponents, you move the decimal place that many positions to the right, adding zeros as needed. For negative exponents, you move the decimal place that many positions to the LEFT, adding zeros as needed. And, the special case is this: 100 = 1.
Exactly that ... negative exponents. For example: 1000 = 103 That is a positive exponent. .001 = 10-3 That is a negative exponent. For positive exponents, you move the decimal place that many positions to the right, adding zeros as needed. For negative exponents, you move the decimal place that many positions to the LEFT, adding zeros as needed. And, the special case is this: 100 = 1.
Exponents represent repeated multiplication of a base number, and the rules of exponents state that when multiplying two powers with the same base, you add the exponents (e.g., (a^m \times a^n = a^{m+n})). However, when you have a product with exponents, you cannot simply add the exponents because they represent different operations. Each exponent is tied to its specific base, so adding them would misrepresent the actual multiplication of the numbers involved. For example, (a^m \times b^n) cannot be simplified by adding the exponents since (a) and (b) are different bases.
It can be a problem to do with adding or subtracting or exponents.