Assertion: In a elastic collision `(e = 1)` between two bodies, conservation of kinetic energy holds true. i.e., `(K_(1) + K_(2))_(i) = (K_(1) + K_(2))_(f)`.
Reason: Conservation of momentum holds true i.e., `(P_(1) + P_(2))_(i) = (P_(1) + P_(2))_(f)`.

In which, elastic or inelastic collision, the momentum is conserved ? What about K.E.?

If P(E_(1)) = p_(1) and P(E_(2)) = p_(2) and E_(1) and E_(2) are independent then P( neither E_(1) nor E_(2) )=

Let E_(1) and E_(2) be two independent events such that P(E_(1))=P_(1) and P(E_(2))=P_(2) , describe in words of the events whose probabilities are (i) P_(1)P_(2) (ii) (1-P_(1))P_(2) (iii) 1-(1-P_(1))(1-P_(2)) (iv) P_(1)+P_(2)-2P_(1)P_(2)

Two bodies having moments of inertia I_(1) and I_2 (I_(1) gt I_(2)) have same angular momentum. If E_(1) and E_(2) are their rotational kinetic energies,

If E_(1) and E_(2) are two events such that P(E_(1))=1//4 , P(E_(2)//E_(1))=1//2 and P(E_(1)//E_(2))=1//4 , then

Two balls , having linear momenta vec(p)_(1) = p hat(i) and vec(p)_(2) = - p hat(i) , undergo a collision in free space. There is no external force acting on the balls. Let vec(p)_(1) and vec(p)_(2) , be their final momenta. The following option(s) is (are) NOT ALLOWED for any non -zero value of p , a_(1) , a_(2) , b_(1) , b_(2) , c_(1) and c_(2) (i) vec(p)_(1) = a_(1) hat(i) + b_(1) hat(j) + c_(1) hat(k) , vec(p)_(2) = a_(2) hat(i) + b_(2) hat(j) (ii) vec(p)_(1) = c_(1) vec(k) , vec(p)_(2) = c_(2) hat(k) (iii) vec(p)_(1) = a_(1) hat(i) + b_(1) hat(j) + c_(1) hat(k) ,vec(p)_(2) = a_(2) hat(i) + b_(2) hat(j) - c_(1) hat(k) (iv) vec(p)_(1) = a_(1) hat(i) + b_(1) hat(j) , vec(p)_(2) = a_(2) hat(i) + b_(1) hat(j)

if E_(1) and E_(2) are two events such that P(E_(1))=(1)/(4),P((E_(2))/(E_(1)))=(1)/(2) and P=((E_(1))/(E_(2)))=(1)/(4)

If bar(P_(1)P_(2)) is perpendicular to bar(P_(2)P_(3)) ,then the value of k is where P_(1)(k,1,-1),P_(2)(2k,0,2) &, P_(3)(2+2k,k,1)

Two bulbs each of 60 W and 80 W power are used for (1/4)th a day and (1/2) a day, respectively. Write the following steps in a sequential order to find the total number of units consumed by them when they are used for 30 days. (a) Now, multiply E with 30, to get the energy consumed by them in 30 days. (b) Find the electric energy consumed by each bulb in a day using E_(1)=P_(1)t_(1) and E_(2)=P_(2)t_(2) . (c) Note down the powers of the bulbs and the time for which they are used per day as P_(1), P_(2) and t_(1) , t_(2) , respectively. (d) Convert the time into hours. (e) Find the total energy (E) consumed by them in one day, i.e., E=E_(1)+E_(2) . (f) Write the energy in terms of units, i.e., commercial unit of electric energy.