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Question
Prove that: `int_a^b f(x)dx = int_a^b f(a + b - x) * dx`. Hence, find `int_(π/6)^(π/3) sin^2x * dx`
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Solution
Part 1: Proof
We prove:
`int_a^b f(x)dx = int_a^b f(a + b - x) dx`
Proof:
Let I = `int_a^b f(x) dx`
Make substitution:
x = a + b – t
Then, dx = – dt
When x = a,
t = b
when x = b,
t = a
So, I = `int_b^a f(a + b - t)(-dt)`
Reversing limits:
I = `int_a^b f(a + b - t) dt`
Since variable is dummy:
`int_a^b f(x)dx = int_a^b f(a + b - x) dx`
Proved.
Part 2: Evaluate
`int_(π/6)^(π/3) sin^2 x dx`
Using the property:
`int_a^b f(x) dx = int_a^b f(a + b - x)dx`
Here, `a = π/6, b = π/3`
`a + b = π/6 + π/3`
= `π/6 + (2π)/6`
= `(3π)/6`
= `π/2`
So, `int_(π/6)^(π/3) sin^2 x dx = int_(π/6)^(π/3) sin^2 (π/2 - x) dx`
But `sin(π/2 - x) = cos x`
So, `int_(π/6)^(π/3) sin^2 x dx = int_(π/6)^(π/3) cos^2 x dx`
Now add both integrals:
2I = `int_(π/6)^(π/3) (sin^2x + cos^2x) dx`
2I = `int_(π/6)^(π/3) 1 dx`
2I = `[x]_(π//6)^(π//3)`
2I = `π/3 - π/6`
2I = `π/6`
I = `π/12`
