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8 min read•june 18, 2024
Anusha Tekumulla
Kashvi Panjolia
Anusha Tekumulla
Kashvi Panjolia
In this unit, you’ll learn how to find the average value of a function, model particle motion and net change, and determine areas and volumes. Specifically, you should develop an understanding of integration that can be transferred across many other applications. You'll start to see how integration is useful in the fields of physics and engineering, and exercise your drawing skills as you draw sketches to visualize 2D and 3D shapes. With integrals, you won’t have to use any of the Riemann sums you learned earlier in the year. It is crucial to understand the general steps for solving each problem in this unit. This unit should be about 10-15% of the AP Calculus AB Exam or 6-9% of the AP Calculus BC Exam.
In calculus, the average value of a function is the value that the function would take at a single point if the area under the curve were equal to the area of a rectangle with the same width and height as the curve. In other words, it is a way to measure the "center of mass" or "balance point" of a function.
The average value of a function f(x) over the interval [a,b] is given by the formula:
If you have taken or are taking a physics course, then you already know what position, velocity, and acceleration are. If you haven't heard these terms before, you only need to know that position is where an object is at a moment in time, velocity is the rate of change (read as derivative) of the position as a function of time, and acceleration is the rate of change (read as derivative) of velocity as a function of time.
Definite integrals can be used to calculate the displacement and total distance traveled for a particle in linear motion over a certain interval of time.
Displacement is a vector quantity that represents the change in position of an object. It can be found by taking the definite integral of the velocity function with respect to time. This is because velocity is the rate of change of position, and the definite integral of a rate of change is the change itself.
On the other hand, the total distance traveled is a scalar quantity that represents the total distance covered by the object, regardless of its final position. It can be found by taking the definite integral of the speed function with respect to time. This is because speed is the magnitude of the velocity and the definite integral of a scalar function represents the accumulated change in the function over a certain interval.
The definite integral, as you already know, is a fundamental concept in calculus that allows us to calculate the accumulated change of a function over a certain interval. It can be used to express information about accumulation and net change in many applied contexts, such as physics, engineering, economics, and many others.
Integration can be used to calculate the total cost of producing a product, the total revenue or cost of a company, the total distance covered by a moving object, and much more. You will be asked on the AP exam to use definite integrals to compute an answer to many real-world scenarios, such as the amount of water leaking from a tank, through word problems.
Finding the area between two curves using integrals involves calculating the definite integral of the difference between the two functions over a given interval. The process is similar whether the curves are functions of x or y.
When the curves are functions of x, we need to find the definite integral of the difference between the two functions, f(x) and g(x), with respect to x over the interval [a, b]. The definite integral representing the area between the curves is given by:
The process of finding the area between two curves that intersect at multiple points is as follows:
Consider the graph of two functions below. The two functions intersect at three points and create two equal sections of area between them.
Finding the volume of a function using a square or rectangular cross-section and integrals involves using the method of slicing, where the function is represented as a solid of revolution formed by rotating a two-dimensional region about an axis to create a three-dimensional shape.
The process for finding the volume of a function using a square or rectangular cross-section is as follows:
The definite integral representing the volume of a function using a square cross-section is given by:
∫ (f(x))^2 dx
The function is squared here because that is the formula for the area of a square (squaring the side length). For a rectangle, the formula for the volume becomes
∫ (f(x))*w dx
The area of a triangle is 1/2bh, so applying that to the basic integration formula we have been using, we get
∫ (1/2)*(f(x))*w dx
The area of a semicircle is found by halving the area of a circle. Using (1/2)πr^2, the formula is
∫ (1/2)(π(f(x))^2)*w dx
As you can see, the volume of a cross-section is determined by the shape of a cross-section. You will likely need to create quick sketches to visualize these 3D shapes, so make sure your pencils are sharpened. ✏️
The disk method is used to find the volume of a solid of revolution when the cross-section of the solid is a disk (circular) shape, so we use the formula for the area of the circle and apply it to our integral:
∫ π*(f(x))^2 dx
These same concepts are used to rotate a function around a horizontal or vertical line other than the x-or y-axis, but with some additional steps.
The washer method is a method used to find the volume of a solid of revolution obtained by rotating a two-dimensional region about an axis. It is similar to the disk method but instead of using disks to find the volume, it uses "washers" which are ring-shaped objects with an inner and outer radius. The washer method is used when the cross-section of the solid is not a disk shape but a ring shape.
Instead of a disk, we find the area of the washer cross-section. This area is given by π*(R^2 - r^2), where R is the outer radius and r is the inner radius of the washer. Then, we integrate as before to find the total volume of our shape. Below is the formula for the washer method:
In order to find the total distance traveled of an object, we need to calculate the arc length of the velocity function for that object. Arc length is a measure of the distance along the curved path of a function, such as a circle or a parabola. In calculus, the arc length of a function can be calculated using integrals. There is only one formula you need to memorize to calculate the arc length of a curve in the Cartesian plane:
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