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5 min readโขjuly 11, 2024
Dylan Black
Dylan Black
The Riemann Sum is a way of approximating the area under a curve on a certain interval [a, b] developed by Bernhard Riemann. The way a Riemann sum works is that it approximates the area by summing up the area of rectangles and then finding the area as the number of rectangles increases to infinity with an infinitely thin width. The following gif may give you a better visual example:
The use of sigma here makes sense since we're summing together a bunch of rectangles. Now, let's tackle the inside of the sum, the f(xk)*ฮx. Remember, we're summing together theย areas of rectangles, so this must be the area of some rectangle. Recall that A = bh (or alternatively A = lw) for rectangles. So one of these must be the height of our rectangles, the other must be our width.
You can see in the image that ฮx = (b-a)/n. What does this mean? Our area is being taken on the interval [a, b], so b-a is just the length of our interval. For example, if we were finding the area on the interval [3, 8], b - a = 5. Similarly, n is the number of rectangles we have (in a perfect Riemann sum, n approaches infinity). Therefore, (b-a)/n is the equivalent of saying we're taking our interval and chopping it up into n sized pieces on that interval. Here's a visual:
If ฮx is the width of our rectangles, f(xk) must be the height! This makes pretty intuitive sense since, for some x value, f(x) tells you essentially the height of the graph at that x. What is k, though? k tells us essentially what rectangle we're on. So for example, at k = 1, we are looking at the first rectangle. Well, how do we find f(xk)? First, we must find xk itself. You'll see in the formula above that xk = a + kฮx. Let's think about this for a second. a is our initial value, our starting point on our interval. k is what rectangle we're on and ฮx is the width of each rectangle. xk, therefore, is a way of calculating the x value of each rectangle. In this instance, we're looking at the right x value of each. If we start at k = 0, we have aย left Riemannย sum.
So imagine you are given this equation: f(x) = x^2. Your interval is [0,5] and n = 5. For the purposes of simplicity, I am going to demonstrate a Left Riemann Sum.
Equation: f(x) = x^2 Interval: [a,b] and in the case of this problem [1,5] - these are the parameters for the section under the curve that you are estimating N: n=4 - this number determines how many rectangles you are splitting the section under the curve into. (Note: More rectangles = more precision, but also means more work)
(1)(1) + (1)(4) + (1)(9) + (1)(16) = 30
A =ย ฮx( f(x1) + f(x2) + f(x3)...)
^In simplest terms, this equation will help you solve any Riemann Sum. Note that all the steps are the same for Right Riemann Sums except for #3. Just remember to use the top left corner of your rectangles for each Left Riemann Sum and the top right corner for each Right Riemann Sum.
For some quick background, when you use the areas of rectangles to estimate the area under a curve, that estimate is a Riemann Sum. When using this method you have two options: a Left Riemann Sum or a Right Riemann Sum. But what's the difference and when should you use each one?
Right Riemann Sum: The right corner of each rectangle touches the curve.
Increasing Function: Overestimate
Decreasing Function: Underestimate
Increasing Function: Underestimate
Decreasing Function: Overestimate
๐ 2007 AP Calculus AB Right Reimann Sum FRQ
๐2009 AP Calculus AB Left Reimann Sum FRQ
๐2011 AP Calculus AB Trapezoidal Reimann Sum FRQ
๐2012 AP Calculus BC Midpoint Reimann Sum FRQย
You may have noticed earlier that we discussed whether or not a Riemann sum is an overapproximation or an underapproximation. This depends on two things: if the function is increasing or decreasing, and if we are using a righthand Riemann sum or a lefthand Riemann sum. If a function is increasing, lefthand is an underapproximation and righthand is an overapproximation and vice versa.
Riemann sums are an incredibly powerful tool when approximating areas, and they can even be used, when infinitesimal, to calculate exact areas. Approximating areas is useful, especially when you're dealing with a function where finding an anti-derivative is difficult or would take too long. Using Riemann sums in calculus opens up a whole new world of integration
With Reimann Sums, it is important to master all Applications of Integration.
Start readingย Unit 8: Applications of Integration
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