The formula of population density is ………. (A) `N_(t+1) = N_(t) + [(B-I)-(D+E)]` (B) `N_(t+1) = N_(t) + [(B+I)-(D+E)]` (C) `N_(t+1) = N_(t) + [(D+E)-(B+I)]` (D) `N_(t+1) = N_(t) + [(B+I)-(D-E)]`

The velocity - time graph of a particle in one dimensional motion is shown in figure. Which of the following formulae are correct for describing the motion of the particle over the time- interval t _(1) to t _(2) : (a) x (t _(2)) = x (t _(1)) +v (t _(2) - t _(1)) + ((1)/(2)) a (t _(2) - t _(1)) ^(2) (b) v (t_(2)) = v (t_(1)) + a (t _(1)))//(t_(2) -t _(1)) (C) v _("average")= (x (t _(2)) -x (t _(1)))//(t_(2) -t _(1)) (d) a _("average")= (v(t _(2)) - v (t _(1))) //(t_(2) -t _(1)) (e) x (t _(2))=x(t_(1)) + v _("average") (t _(2) - t _(1)) + ((1)/(2)) a _("average") (t _(2) -t _(1)) ^(2) (f) c (t _(2)) - c (t _(1)) = area under the v-t curve bonunded by the t -axis and the dotted line shown.

For an A.P., show that t_(m) + t_(2n + m) = 2t_( m + n)

If x=a t^2,\ \ y=2\ a t , then (d^2y)/(dx^2)= (a) -1/(t^2) (b) 1/(2\ a t^3) (c) -1/(t^3) (d) -1/(2\ a t^3)

For any arbitrary motion in space , which of the following relations are true : (a) V_("average")=(1//2)(v(t_(1))+v(t_(2))) (b) V_("average")=[r(t_(2))-r(t_(1))]//(t_(2)-t_(1)) (c ) V(t)=V(0)+at (d) r(t) =r(0)+v(0)T+(1//2)at^(2) (e ) a_("average")=[v(t_(2))-v(t_(1))]//(t_(2)-t_(1)) (The average stands for average of the quantity over the time interval t_(1)" to "t_(2))

If t_(1)=1,t_(r )-t_( r-1)=2^(r-1),r ge 2 , find sum_(r=1)^(n)t_(r ) .

If N_(t) = N_(o)e^(lambdat) then number of disintefrated atoms between t_(1) to t_(2) (t_(2) gt t_(1)) will ve :-

Let R be a relation on N xx N defined by (a,b) R(c, d) hArr a + d= b + c for all (a,b) (c,d) in N xx N show that, (a,b) R (c, d) rArr (c, d) R (a, b) for all (a, b) (c, d) in N xx N

Let R_(t) represents activity of a sample at an insant and N_(t) represent number of active nuclei in the sample at the instant. T_(1//2) represents the half life. {:(,"Column I",,"Column II"),((A),t=T_(1//2),(p),R_(t)=(R_(0))/(2)),((B),t=(T_(1//2))/(ln2),(q),N_(0)-N_(t)=(N_(0))/(2)),((C),t=(3)/(2)T_(1//2),(r),(R_(t)-R_(0))/(R_(0)) = (1-e)/(e)),(,,(s),N_(t)=(N_(0))/(2sqrt(2))):}

Let R be a relation on N xx N defined by (a,b) R(c, d) hArr a + d= b + c for all (a,b) (c,d) in N xx N show that, (a, b) R (a,b) for all (a, b) in N xx N