There are two damped oscilaltions with the following period` T` and damping coefficients `beta: T_(1)=0.10 ms, beta_(1)=100 s^(-1)`
`T_(2)=10 ms, beta=10 s^(-1)`. Which of them decays faster ?

A point performs damped oscilaltions with frequency omega and dampled coefficient beta . Find the velocity amplitude of the point as a function of time t if at the moment t=0 (a) its displacement amplitude is equal to a_(0), (b) the displacement of the point x(0)=0 and its velocity projection v_(x(0)=dot(x_(0))

Measure of two quantites along with the precision of respective measuring instrument is A = 2.5 ms^(-1) +- 0.5 ms^(-1) B = 0.10 s +- 0.01s The value of AB will be

The position vector vec(r) of a particle of mass m is given by the following equation vec(r) (t) = at^(3) hat(i) + beta t ^(2) hat(j) " where " alpha = 10//3 ms^(-3),beta = 5 ms^(-2) and m = 0 . 1 kg . At t = 1 s, which of the following statement (s) is (are) true about the particle ?

The position vector vacr of the z-component of vecL is 55ma^2omega . Following equation vacr(t)= alphat^3hati+beta^2hatj, where alpha = 10//3ms^(-3), beta = 5 ms^(-2) and m = 0.1kg. At t=1s, which of the following statement (s) is (are) true about the particle?

If in an AP,t_(1)=log_(10)a,t_(n+1)=log_(10)b and t_(2n+1)=log_(10) then a,b,c are in

In the projectile motion shown is figure, given t_(AB) = 2s then (g = 10 ms^(-2))

A body is thrown vetically upward at t = 0 . It is at a height 80 m at two instant t_(1) and t_(2) , then t_(1) t_(2) is: (Take g = 10 m//s^(2) )

The relation between time and displacement x is t =alphax^(2) + betax , where alpha and beta are constants. (Take alpha =2 m^(-2) s, beta = 1m^(-1)s)

Measure of two quantities along with the precision of respective measuring instrument is A=2.5ms^(-1)+-0.5ms^(-1) ,B=0.10s+-0.01s . The value of AB will be