- #1
prudens2010
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Code:
Let f =
x, for 0<=x<=1
1, for 1<x
alpha =
x^2, for 0<=x<=1
1, for 1<x
Find Integral (f) d(alpha) -- from 0 to 23
pls help!
Let f =
x, for 0<=x<=1
1, for 1<x
alpha =
x^2, for 0<=x<=1
1, for 1<x
prudens2010 said:Code:Let f = x, for 0<=x<=1 1, for 1<x alpha = x^2, for 0<=x<=1 1, for 1<x
Find Integral (f) d(alpha) -- from 0 to 23
pls help!
The Riemann Stieltjes integral is a type of integral that extends the concept of the Riemann integral to functions that are not necessarily continuous. It is used to find the area under a curve that is defined by a function and a second function, known as the integrator function.
The main difference between the Riemann and Riemann Stieltjes integral is that in the Riemann integral, the function is integrated with respect to the variable of integration, while in the Riemann Stieltjes integral, the function is integrated with respect to another function, known as the integrator function.
To calculate the Riemann Stieltjes integral, you first divide the interval of integration into subintervals. Then, you evaluate the function at each point of the subintervals and multiply it by the difference between the values of the integrator function at the endpoints of the subinterval. Finally, you add all these values together and take the limit as the width of the subintervals approaches zero.
The Riemann Stieltjes integral has many applications in physics, engineering, economics, and other fields where the concept of accumulation is important. It is also used in probability theory, where it is used to calculate expectations of random variables.
The Riemann Stieltjes integral has some limitations, such as the integrator function must be monotonic and have a finite number of discontinuities. It also cannot be used to integrate functions that are not bounded or have infinite discontinuities. In these cases, other types of integrals, such as the Lebesgue integral, may be used instead.