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Quickly determine the range of a function using these equations and examples
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The range of a function is the set of numbers that the function can produce. In other words, it is the set of y-values that you get when you plug all of the possible x-values into the function. This set of possible x-values is called the domain . If you want to know how to find the range of a function, just follow these steps.

Method 1
Method 1 of 4:

Finding the Range of a Function Given a Formula

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  1. Let's say the formula you're working with is the following: f(x) = 3x 2 + 6x -2 . This means that when you place any x into the equation, you'll get your y value. This is the function of a parabola.
  2. If you're working with a straight line or any function with a polynomial of an odd number, such as f(x) = 6x 3 +2x + 7, you can skip this step. But if you're working with a parabola, or any equation where the x-coordinate is squared or raised to an even power, you'll need to plot the vertex. To do this, just use the formula -b/2a to get the x coordinate of the function 3x 2 + 6x -2, where 3 = a, 6 = b, and -2 = c. In this case -b is -6, and 2a is 6, so the x-coordinate is -6/6, or -1.
    • Now, plug -1 into the function to get the y-coordinate. f(-1) = 3(-1) 2 + 6(-1) -2 = 3 - 6 -2 = -5.
    • The vertex is (-1,-5). Graph it by drawing a point where the x coordinate is -1 and where the y-coordinate is -5. It should be in the third quadrant of the graph.
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  3. To get a sense of the function, you should plug in a few other x-coordinates so you can get a sense of what the function looks like before you start to look for the range. Since it's a parabola and the x 2 coordinate is positive, it'll be pointing upward. But just to cover your bases, let's plug in some x-coordinates to see what y coordinates they yield:
    • f(-2) = 3(-2) 2 + 6(-2) -2 = -2. One point on the graph is (-2, -2)
    • f(0) = 3(0) 2 + 6(0) -2 = -2. Another point on the graph is (0,-2)
    • f(1) = 3(1) 2 + 6(1) -2 = 7. A third point on the graph is (1, 7).
  4. Now, look at the y-coordinates on the graph and find the lowest point at which the graph touches a y-coordinate. In this case, the lowest y-coordinate is at the vertex, -5, and the graph extends infinitely above this point. This means that the range of the function is y = all real numbers ≥ -5 .
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Method 2
Method 2 of 4:

Finding the Range of a Function on a Graph

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  1. Look for the lowest y-coordinate of the function. [1] Let's say the function reaches its lowest point at -3. This function could also get smaller and smaller infinitely, so that it doesn't have a set lowest point -- just infinity.
  2. Let's say the highest y-coordinate that the function reaches is 10. [2] This function could also get larger and larger infinitely, so it doesn't have a set highest point -- just infinity.
  3. This means that the range of the function, or the range of y-coordinates, ranges from -3 to 10. So, -3 ≤ f(x) ≤ 10. That's the range of the function.
    • But let's say the graph reaches its lowest point at y = -3, but goes upward forever. Then the range is f(x) ≥ -3 and that's it.
    • Let's say the graph reaches its highest point at 10 but goes downward forever. Then the range is f(x) ≤ 10.
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Method 3
Method 3 of 4:

Finding the Range of a Function of a Relation

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  1. A relation is a set of ordered pairs with of x and y coordinates. You can look at a relation and determine its domain and range. Let's say you're working with the following relation: {(2, –3), (4, 6), (3, –1), (6, 6), (2, 3)}. [3]
  2. To find the range of the relation, simply write down all of the y-coordinates of each ordered pair: {-3, 6, -1, 6, 3}. [4]
  3. You'll notice that you have listed "6" two times. Take it out so that you are left with {-3, -1, 6, 3}. [5]
  4. Now, reorder the numbers in the set so that you're moving from the smallest to the largest, and you have your range. The range of the relation {(2, –3), (4, 6), (3, –1), (6, 6), (2, 3)} is {-3,-1, 3, 6}. You're all done. [6]
  5. For a relation to be a function, every time you put in one number of an x coordinate, the y coordinate has to be the same. For example, the relation {(2, 3) (2, 4) (6, 9)} is not a function, because when you put in 2 as an x the first time, you got a 3, but the second time you put in a 2, you got a four. For a relation to be a function, if you put in the same input, you should always get the same output. If you put in a -7, you should get the same y coordinate (whatever it may be) every single time. [7]
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Method 4
Method 4 of 4:

Finding the Range of a Function in a Word Problem

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  1. Let's say you're working with the following problem: "Becky is selling tickets to her school's talent show for 5 dollars each. The amount of money she collects is a function of how many tickets she sells. What is the range of the function?"
  2. In this case, M represents the amount of money she collects, and t represents the amount of tickets she sells. However, since each ticket will cost 5 dollars, you'll have to multiply the amount of tickets sold by 5 to find the amount of money. Therefore, the function can be written as M(t) = 5t.
    • For example, if she sells 2 tickets, you'll have to multiply 2 by 5 to get 10, the amount of dollars she'll get.
  3. To determine the range, you must first find the domain. The domain is all of the possible values of t that work in the equation. In this case, Becky can sell 0 or more tickets - she can't sell negative tickets. Since we don't know the number of seats in her school auditorium, we can assume that she can theoretically sell an infinite number of tickets. And she can only sell whole tickets; she can't sell 1/2 of a ticket, for example. Therefore, the domain of the function is t = any non-negative integer.
  4. The range is the possible amount of money that Becky can make from her sale. You have to work with the domain to find the range. If you know that the domain is any non-negative integer and that the formula is M(t) = 5t , then you know that you can plug any non-negative integer into this function to get the output, or the range. For example, if she sells 5 tickets, then M(5) = 5 x 5, or 25 dollars. If she sells 100, then M(100) = 5 x 100, or 500 dollars. Therefore, the range of the function is any non-negative integer that is a multiple of five.
    • That means that any non-negative integer that is a multiple of five is a possible output for the input of the function.
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Expert Q&A

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  • Question
    What is range on a graph?
    David Jia
    Math Tutor
    David Jia is an Academic Tutor and the Founder of LA Math Tutoring, a private tutoring company based in Los Angeles, California. With over 10 years of teaching experience, David works with students of all ages and grades in various subjects, as well as college admissions counseling and test preparation for the SAT, ACT, ISEE, and more. After attaining a perfect 800 math score and a 690 English score on the SAT, David was awarded the Dickinson Scholarship from the University of Miami, where he graduated with a Bachelor’s degree in Business Administration. Additionally, David has worked as an instructor for online videos for textbook companies such as Larson Texts, Big Ideas Learning, and Big Ideas Math.
    Math Tutor
    Expert Answer
    The range is all of the possible y values that can exist on a graph. What are all of the numbers that could successfully be plugged in as y coordinates? What are all of the places that the graph vertically touches? Answering these questions helps you find the range of a graph.
  • Question
    How can I find range of a function using limits?
    Community Answer
    If a function doesn't have a maximum (or a minimum), then you might have to evaluate a limit to find its range. For example, f(x) = 2^x doesn't have a minimum but the limit as x approaches negative infinity is 0, and the limit as x approaches positive infinity is infinity. So the range is (0,infinity) using open intervals because neither limit is ever reached, only approached.
  • Question
    What is AM = GM concept for finding range?
    Community Answer
    This refers to the Arithmetic Mean (AM) - Geometric Mean (GM) inequality, which states that for positive numbers, the AM is always at least as large as the GM. In some cases, this can be used to find upper or lower bounds for the range of a function. For example, find the range of f(x) = x^2 + 1/x^2. It obviously has a minimum, but where? Many calculus students will immediately take a derivative. This works fine, but if you know the AM-GM inequality, there is no need for the heavy artillery of calculus. f(x) = 2 * AM(x^2, 1/x^2). The GM of (x^2, 1/x^2) is 1, and the since the AM is more than that, f(x) is always at least 2, and the range of f is [2, infinity).
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      Tips

      • For more difficult cases, it may be easier to draw the graph first using the domain (if possible) and then determine the range graphically.
      • Check to see if the function repeats. Any function which repeats along the x-axis will have the same range for the entire function. For instance, f(x) = sin(x) has a range between -1 and 1.
      • See if you can find the inverse function. The domain of a function's inverse function is equal to that function's range.
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      Article Summary X

      To find the range of a function in math, first write down whatever formula you’re working with. Then, if you’re working with a parabola or any equation where the x-coordinate is squared or raised to an even power, use the formula -b divided by 2a to get the x- and then y-coordinates. You can skip this step if you’re working with a straight line or any function with a polynomial of an odd number. Next, plug in a few other x-coordinates and solve for their y-coordinates. Finally, plot those points on a graph to see the range of your function. For more on finding the range of a function, including for a relation and in a word problem, scroll down!

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