R is :

Statement I In a Delta ABC, if a lt b lt c and r is inradius and r_(1) , r_(2) , r_(3) are the exradii opposite to angle A,B,C respectively, then r lt r_(1) lt r_(2) lt r_(3). Statement II For, DeltaABC r_(1)r_(2)+r_(2)r_(3)+r_(3)r_(1)=(r_(1)r_(2)r_(3))/(r)

Let there be a spherical symmetric charge density varying as p(r )=p_(0)(r )/(R ) upto r = R and rho(r )=0 for r gt R , where r is the distance from the origin. The electric field at on a distance r(r lt R) from the origin is given by -

Prove that 2R cos A = 2R + r - r_(1)

If I is the incenter of Delta ABC and R_(1), R_(2), and R_(3) are, respectively, the radii of the circumcircle of the triangle IBC, ICA, and IAB, then prove that R_(1) R_(2) R_(3) = 2r R^(2)

r gt s {:("Quantity A","Quantity B"),((r+s)(r-s),(s+r)(s-r)):}

In Figure, P Q R S and A B R S are parallelograms and X is any point on side B R . Show that : a r(||^(gm)P Q R S)=a r(||^(gm)A B R S) , a r(triangle A X S)=1/2a r(||^(gm) P Q R S)

Show that + : R xx R ->R and xx : R xx R ->R are commutative binary operations, but - : RxxR ->R and -: : R_ *xxR_* ->R_* are not commutative.

cosA+cosB+cosC is equal to (A) r/R (B) R/r (C) 1 (D) 1+r/R

If r,r_(1) ,r_(2), r_(3) have their usual meanings , the value of 1/(r_(1))+1/(r_(2))+1/(r_(3)) , is

A satellite of mass m orbits the earth in an elliptical orbit having aphelion distance r_(a) and perihelion distance r_(p) . The period of the orbit is T. The semi-major and semi-minor axes of the ellipse are (r_(a) + r_(p))/(2) and sqrt(r_(p)r_(a)) respectively. The angular momentum of the satellite is: (A) (2m pi (r_(B)+r_(p)) sqrt(r_(a) r_(p)))/T (B) (m pi (r_(a)+r_(p)) sqrt(r_(a) r_(p)))/(2T) (C) (m pi (r_(a)+r_(p)) sqrt(r_(a)r_(p)))/(4T) (D) (mpi (r_(a)+r_(p)) sqrt(r_(a)r_(p)))/T