For each t`in R`,let[t]be the greatest integer less than or equal to t. Then
`underset(xto1^+)lim((1-absx+sinabs(1-x))sin(pi/2[1-x]))/(abs(1-x)[1-x])`

For each t in R ,let[t]be the greatest integer less than or equal to t. Then lim_(xto1^+)((1-absx+sinabs(1-x))sin(pi/2[1-x]))/(abs(1-x)[1-x])

For each t in RR, let [t] be the greatest integer less than or equal to t. Then, lim_(x rarr 1+) ((1-|x|+sin|1-x|)sin(pi/2[1-x]))/(|1-x|[1-x])

For each x in R , let [x]be the greatest integer less than or equal to x. Then lim_(xto1^+) (x([x]+absx)sin[x])/absx is equal to

Let [x] denote the greatest integer less than or equal to x . Then, int_(1)^(-1)[x]dx=?

Let f(x)=[x^(2)+1],([x] is the greatest integer less than or equal to x) . Ther

Let [x] denote the greatest integer less than or equal to x . Then, int_(0)^(1.5)[x]dx=?

let [x] denote the greatest integer less than or equal to x. Then lim_(xto0) (tan(pisin^2x)+(abs.x-sin(x[x]))^2)/x^2

If [x] denotes the greatest integer less than or equal to x, then the value of lim_(x rarr1)(1-x+[x-1]+[1-x]) is

For each t in R let [t] be the greatest integer less than or equal to t then lim_(x rarr0^(+))x([(1)/(t)]+[(2)/(t)]+...+[(15)/(t)])(1) is equal to 0(2) is equal to 15(3) is equal to 120 (4) does not exist (in R)