`f(x)=sinx+int_(-pi//2)^(pi//2)(sinx+tcosx)f(t)dt` The range of `f(x)` isA. `[-(sqrt(3))/2,(sqrt(3))/2]`B. `[-(sqrt(5))/3,(sqrt(5))/3]`C. `[-(sqrt(5))/2,(sqrt(5))/2]`D. none of these

`f(x)=sinx+int_(-pi//2)^(pi//2)(sinx+tcosx)f(t)dt` The range of `f(x)`

1.	`f(x)=sinx+int_(-pi//2)^(pi//2)(sinx+tcosx)f(t)dt` The range of `f(x)` isA. `[-(sqrt(3))/2,(sqrt(3))/2]`B. `[-(sqrt(5))/3,(sqrt(5))/3]`C. `[-(sqrt(5))/2,(sqrt(5))/2]`D. none of these
Answer» Correct Answer - B `f(x)=sinx+sin int_(-pi//2)^(pi//2) f(t)dt+cosx int_(-pi//2)^(pi//2) tf(t)dt` `=sinx (1+int_(-pi//2)^(pi//2) f(t)dt)+cosx int_(-pi//2)^(pi//2) tf(t)dt` `=Asinx+Bcosx` Thus, `A=1+int_(-pi//2)^(pi//2) f(t)dt` `=1+int_(-pi//2)^(pi//2) (Asint+Bcost)dt` `=1+2Bint_(0)^(pi//2) cost dt` `=A=1+2B` ............1 `B=int_(-pi//2)^(pi//2) tf(t)dt` `=int_(-pi//2)^(pi//2)t(Asint+Bcost)dt` `=2Aint_(0)^(pi//2) t sin tdt` `=2A[-tcost+sint]_(0)^(pi//2)` `:.B=2A` From equations 1 and 2 we get `A=-1//3, B=-2//3` `:.f(x)=-1/3(sinx+2cosx)` Thus, the range fo `f(x)` is `[-(sqrt(5))/3,(sqrt(5))/3]` `f(x)=-1/2(sinx+2cosx)` `=-(sqrt(5))/3 sin (x+tan^(-1)2)` `=-(sqrt(5))/3cos(x-"tan"^(-1)1/2)` `f(x)` in invertible if `-(pi)/2 le x=tan^(-1)2le(pi)/2` or `-(pi)/2-tan^(-1)2 le xle (pi)/2 -tan^(-1) 2` or `0lex-"tan"^(-1)1/2 le pi` or `"tan"^(-1)1/2 le x le pi+"tan"^(-1)1/2` or `pi le x-"tan"^(-1)1/2le 2pi` or `x epsilon [pi+cot^(-1)2, 2pi +cot^(-1) 2]` `int_(0)^(pi//2) f(x)dx=-1/3int_(0)^(pi//2) (sinx+2cosx)dx` `=-1/3[-cosx+2sinx]_(0)^(pi//2) =-1`

Consider the integral `I=int_(0)^(2pi)(dx)/(5-2cosx)` Making the substitution `"tan"1/2x=t`, we have `I=int_(0)^(2pi)(dx)/(5-2cosx)=int_(0)^(0)(2dt)/((1+t^(2))[5-2(1-t^(2))//(1+t^(2))])=0` The result is obviously wrong, since the integrand is positive and consequently the integral of this function cannot be equal to zero. Find the mistake.
The area bounded by the curves `y=cosx` and `y=sinx` between the ordinates `x=0` and `x=(3pi)/2` isA. `4sqrt(2) + 2`B. `4sqrt(2) +1`C. `4sqrt(2) + 1`D. `4sqrt(2) - 2`
Obtain the area enclosed by region bounded by the curves `y = x ln x` and ` y = 2x-2x^(2)`.A. `7//6`B. `7//24`C. `12//7`D. `7//12`
If `I_n=int_0^pi e^x(sinx)^n dx ,` then `(I_3)/(I_1)` is equal toA. `3//5`B. `1//5`C. `1`D. `2//5`
Prove that:`I_n=int_0^oox^(2n+1)e^-x^2dx=(n !)/2,n in Ndot`
If f(x) is continuous and `int_(0)^(9)f(x)dx=4`, then the value of the integral `int_(0)^(3)x.f(x^(2))dx` isA. 2B. 18C. 16D. 4
`lim_(trarr0) int_(0)^(2pi)(|sin(x+t)-sinx|)/(|t|)dx` equalsA. 2B. 4C. 43469D. 1
Given that `lim_(nrarroo) sum_(r=1)^(n) (log_(e)(n^(2)+r^(2))-2log_(e)n)/n = log_(e)2+pi/2-2`, then evaluate : ` lim_(nrarroo) (1)/(n^(2m))[(n^(2)+1^(2))^(m)(n^(2)+2^(2))^(m) "......"(2n^(2))^(m)]^(1//n)`.
`lim_(nrarroo) sum_(r=0)^(n-1) (1)/(sqrt(n^(2)-r^(2)))`
`lim_(nrarroo) (((n+1)(n+2)"........"3n)/(n^(2n)))^(1//n)` is equal to :A. `(27)/(e^(2))`B. `(9)/(e^(2))`C. `3 log3-2`D. `(18)/(e^(4))`