QuantumTheory
Nov30-04, 02:32 PM
Ok.
Im' confused between the difference of definite and indefinite integrals.
\int\limits_a_b
\int
The first integral here which is \int\limits_a_b is about area below a curve.
Where a and b is the difference of the area under the function f(x). The \int\ is just the whole of all of the f(x) dx on an area.
Consider we have an area under the curve.
We will call the function f(x) = x^2
The area under the curve is then defined as:
\int\limits_a_b f(x) dx = dL
The \int\limits_a_b is defined as all of dx of the function f(x) from a to b.
dx is a small infinitely small piece of the area under the curve.
dL is defined as the area.
I do not understand the integral:
\int , which has no limits (a to b).
I know that this integral is backwards differenatation and requires a constant (I don't know what "arbitary" means, I think it means "fixed"?)
Such that,
\int x^2 = 1/3^2 + C
Help please?
Thanks :wink:
Im' confused between the difference of definite and indefinite integrals.
\int\limits_a_b
\int
The first integral here which is \int\limits_a_b is about area below a curve.
Where a and b is the difference of the area under the function f(x). The \int\ is just the whole of all of the f(x) dx on an area.
Consider we have an area under the curve.
We will call the function f(x) = x^2
The area under the curve is then defined as:
\int\limits_a_b f(x) dx = dL
The \int\limits_a_b is defined as all of dx of the function f(x) from a to b.
dx is a small infinitely small piece of the area under the curve.
dL is defined as the area.
I do not understand the integral:
\int , which has no limits (a to b).
I know that this integral is backwards differenatation and requires a constant (I don't know what "arbitary" means, I think it means "fixed"?)
Such that,
\int x^2 = 1/3^2 + C
Help please?
Thanks :wink: