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Evaluate: `int_0^3 x^2 (3 - x)^(5/2) "d"x`
Concept: undefined >> undefined
Evaluate: `int_0^1 "t"^2 sqrt(1 - "t") "dt"`
Concept: undefined >> undefined
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Evaluate: `int_0^(1/2) 1/((1 - 2x^2) sqrt(1 - x^2)) "d"x`
Concept: undefined >> undefined
Evaluate: `int_0^(pi/4) (sec^2x)/(3tan^2x + 4tan x + 1) "d"x`
Concept: undefined >> undefined
Evaluate: `int_(1/sqrt(2))^1 (("e"^(cos^-1x))(sin^-1x))/sqrt(1 - x^2) "d"x`
Concept: undefined >> undefined
Evaluate: `int_0^1 (log(x + 1))/(x^2 + 1) "d"x`
Concept: undefined >> undefined
Evaluate: `int_0^pi x*sinx*cos^2x* "d"x`
Concept: undefined >> undefined
Evaluate: `int_(-1)^1 (1 + x^2)/(9 - x^2) "d"x`
Concept: undefined >> undefined
Evaluate: `int_0^1 (1/(1 + x^2)) sin^-1 ((2x)/(1 + x^2)) "d"x`
Concept: undefined >> undefined
Evaluate: `int_0^(pi/4) (cos2x)/(1 + cos 2x + sin 2x) "d"x`
Concept: undefined >> undefined
Evaluate: `int_0^(pi/4) log(1 + tanx) "d"x`
Concept: undefined >> undefined
Evaluate: `int_0^pi 1/(3 + 2sinx + cosx) "d"x`
Concept: undefined >> undefined
Evaluate: `int_0^(π/4) sec^4 x dx`
Concept: undefined >> undefined
Find the distance between the parallel lines `x/2 = y/-1 = z/2` and `(x - 1)/2 = (y - 1)/-1 = (z - 1)/2`
Concept: undefined >> undefined
If u and v ore differentiable functions of x. then prove that:
`int uv dx = u intv dx - int [(du)/(d) intv dx]dx`
Hence evaluate `intlog x dx`
Concept: undefined >> undefined
`int_0^(π/2) sin^6x cos^2x.dx` = ______.
Concept: undefined >> undefined
If `int_2^e [1/logx - 1/(logx)^2].dx = a + b/log2`, then ______.
Concept: undefined >> undefined
If ax2 + 2hxy + by2 = 0 represents a pair of lines and h2 = ab ≠ 0 then find the ratio of their slopes.
Concept: undefined >> undefined
If θ is the acute angle between the lines represented by ax2 + 2hxy + by2 = 0 then prove that tan θ = `|(2sqrt(h^2 - ab))/(a + b)|`
Concept: undefined >> undefined
Find the approximate value of sin (30° 30′). Give that 1° = 0.0175c and cos 30° = 0.866
Concept: undefined >> undefined
