Evaluate if sin |x| - |x| is differentiable at x = 0.
a) Yes
b) No
Your Answer
The point representing complex number z for which |z – 3| = |z – 5| lies on the locus given by
a) an ellipse
b) a circle
c) a straight line
d) none of these
If f(x) is differentiable and strictly increasing function then the value of is
a) 1
b) 0
c) – 1
d) 2
If f(x) be the interval of find
a) ½
b) 1
c) 2
d) 4
Let f : ℝ → ℝ be a differentiable function and f (1) = 4. Then show that the value of =
equals
a)
b)
c)
d) 4 f (2)
Find the limiting value of when x
Find the limiting value of as x a
The set of all points where the function is differentiable is
b) [0, ∞)
d) (0, ∞)
e) None of these
The value of is
b) – 1
c) 0
d) None of these
Let [.] denotes the greatest integer function and
f(x) = then
a) does not exist
b) f (x) is continuous at x = 0
c) f (x) is not differentiable at x = 0
d)
The function f(x) = denotes the greatest integer function is discontinuous at
a) All x
b) All integer points
c) No x
d) x which is not an integer
a) exists and equals
b) exists and equals
c) does not exist because x – 1 → 0
d) does not exist because the left hand limit is not equal to the right hand limit.
is
a) 2
b) – 2
For x ε R, is equal to
a) e
a) – π
b) π
d) 1
The left hand derivative of f (x) = [x] sinπx at k, k an integer is
a) (k – 1)π
b) (k – 1)π
c) kπ
d) kπ
Let f : ℝ → ℝ be such that f (1) = 3 and then
If where n is a non–zero real number, then a is equal to
a) 0
c) n
given that and
b) is equal to
c) is equal to
d) is equal to 3
Multiple choices
If x + |y| = 2y, then y as a function of x is
a) Defined for all real x
b) Continuous at x = 0
c) Differentiable for all x
d) Such that for x < 0
The function
a) continuous at x = 1
b) differentiable at x = 1
c) continuous at x = 3
d) differentiable at x = 3
Let f (x) = then for all x
b) f is differentiable
c) is continuous
d) f is continuous
If f (x) = then
a) f (x) is continuous ∀ x ℝ
b) f (x) > 0 ∀ x > 1
c) f (x) is continuous but not differentiable ∀ x ℝ
d) f (x) is not differentiable at two points
for x < 0
