doctordiddy said:Homework Statement
∫(0 to 3pi/2) -7|sinx|dx
Homework Equations
The Attempt at a Solution
I am not sure how to treat it as it has an absolute value
i assumed that you could remove the -7 to get
-7∫|sinx| dx
then integrate sinx into -cosx but since there is absolute value i tried to change -cosx to cosx which ended up as
-7cosx
and then doing -7cos(3pi/2)-(-7cos(0))
but this was incorrect. Can anyone give me any hints?
thanks
Sketch the graph of y = sinx from 0 to 3pi/2. From this, can you see what g = |sinx| would look like? Do you then see why integrating sinx to simply -cosx is wrong?doctordiddy said:Homework Statement
∫(0 to 3pi/2) -7|sinx|dx
Homework Equations
The Attempt at a Solution
I am not sure how to treat it as it has an absolute value
i assumed that you could remove the -7 to get
-7∫|sinx| dx
then integrate sinx into -cosx but since there is absolute value i tried to change -cosx to cosx which ended up as
-7cosx
and then doing -7cos(3pi/2)-(-7cos(0))
but this was incorrect. Can anyone give me any hints?
thanks
This is NOT true. If 0 ≤ x ≤ π, then |sinx| = sinx, but for π ≤ x ≤ 2π, sin(x) ≤ 0.Zondrina said:Usually for absolute values you have to break things into cases depending on what values of x you're integrating over.
Notice that from 0 to 3π/2, x≥0? If x≥0, then |sinx| = sinx.
Zondrina said:Consider integrating from x=-2 to x=-1, x<0. If x<0, then |sinx| = -sinx.
The integral of absolute values refers to the process of finding the area under the curve of an absolute value function. It is a mathematical concept used in calculus to determine the total change or accumulation of a quantity over an interval.
To evaluate the integral of absolute values, you must first determine the limits of integration, which are the values that define the beginning and end points of the interval. Then, you can use various integration techniques, such as substitution or integration by parts, to find the antiderivative of the absolute value function. Finally, you can plug in the limits of integration to calculate the definite integral.
Some important properties of integrals of absolute values include linearity, where the integral of a sum is equal to the sum of the integrals, and the fact that the integral of an absolute value function is always positive. Additionally, the integral of an absolute value function can be split into smaller intervals and added together to find the total area.
When integrating a function that contains absolute values, you can rewrite the absolute value as a piecewise function with different expressions for the function depending on whether the input is positive or negative. Then, you can integrate each piece separately and combine the results to find the final integral.
Evaluating integrals of absolute values has many practical applications in fields such as physics, engineering, and economics. For example, it can be used to calculate the displacement of an object moving at a varying velocity, determine the total cost of a changing product, or find the net force acting on an object with varying acceleration.