Let `P, Q` are two points on the curve `y = log_(1/2) (x-0.5)+log_2 sqrt(4x^2- 4x+1)` and P is also on the `x^2+y^2 = 10, Q` lies inside the given circle such that its abscissa is an integer.

Let P and Q are two points on the curve y=log_((1)/(2))(x-0.5)+log_2sqrt(4x^(2)-4x+1) and P is also on the circle x^(2)+y^(2)=10 . Q lies inside the given circle such that its abscissa is an integer. Q. OP*OQ , O being the origin is

Let P and Q are two points on curve y=log_((1)/(2))(x-(1)/(2))+log_(2) sqrt(4x^(2)-4x+1) and P is also on x^(2)+y^(2)=10 . Q lies inside the given circle such that its abscissa is integer. Find the smallest possible value of vec(OP)*vec(OQ) where 'O' being origin.

Let P and Q are two points on curve y=log_((1)/(2))(x-(1)/(2))+log_(2) sqrt(4x^(2)-4x+1) and P is also on x^(2)+y^(2)=10 . Q lies inside the given circle such that its abscissa is integer. find the largest possible value of |vec(PQ)| .

If A=log_(1/2) (1/2-x)+log_2sqrt(4x^2-4x+1) and A^2+B^2=10 then

The fixed point P on the curve y=x^(2)-4x+5 such that the tangent at P is perpendicular to the line x+2y-7=0 is given by

Let P and Q be two points on the curves x^2+y^2=2 and (x^2)/8+y^2/4 =1 respectively. Then the minimum value of the length PQ is

The tangent at a point P on the curve y =ln ((2+ sqrt(4-x ^(2)))/(2- sqrt(4-x ^(2))))-sqrt(4-x ^(2)) meets the y-axis at T, then PT^(2) equals to :

If log_(0.5)log_(5)(x^(2)-4)>log_(0.5)1, then' x' lies in the interval

P(sqrt2,sqrt2) is a point on the circle x^2+y^2=4 and Q is another point on the circle such that arc PQ= 1/4 circumference. The co-ordinates of Q are