Suppose \(\displaystyle f\,:\, \mathbb{R}\, \rightarrow \, \mathbb{R}\) is an integrable function satisfying the following:
. . . . .\(\displaystyle \int_{-2}^3\, f(x)\, dx\, =\, 11\) and \(\displaystyle \int_{-2}^0\, f(x)\, dx\, =\, 9\)
Given that \(\displaystyle f\) is a periodic function, and \(\displaystyle f(x)\, =\, f(x\, +\, 2)\) is always true, find:
. . . . .\(\displaystyle \int_2^3\, f(x)\, dx\)
My work: So \(\displaystyle \int_{-2}^0\, f(x)\, dx\, =\, 9\)
Since it is a periodic function then
[image] = -9
That means
\(\displaystyle \int_2^3\, f(x)\, dx\, =\, 11\)
but it is the incorrect answer, any help would be appreciated, I'm not picking something up
. . . . .\(\displaystyle \int_{-2}^3\, f(x)\, dx\, =\, 11\) and \(\displaystyle \int_{-2}^0\, f(x)\, dx\, =\, 9\)
Given that \(\displaystyle f\) is a periodic function, and \(\displaystyle f(x)\, =\, f(x\, +\, 2)\) is always true, find:
. . . . .\(\displaystyle \int_2^3\, f(x)\, dx\)
My work: So \(\displaystyle \int_{-2}^0\, f(x)\, dx\, =\, 9\)
Since it is a periodic function then
[image] = -9
That means
\(\displaystyle \int_2^3\, f(x)\, dx\, =\, 11\)
but it is the incorrect answer, any help would be appreciated, I'm not picking something up
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