The XI^(th) class students of ALLEN desi...

The `XI^(th)` class students of ALLEN designed a rocket. The rocket was launched from cycle stand of ALLEN straight up into the air. At `t = 0`, the rocket is at `y = 0` with `V_(y) (t = 0) = 0`. The velocity of the rocket is given by: `V_(y) = (24t - 3t^(2))m//s` for `0 le t le t_(b)` where `t_(b)` is the time at which fuel burns out. vertically upward direction is taken as positive. `(g = 10m//s^(2))`
The expression for the acceleration `a_(y)(t)` valid at all times in the interval `0 lt t lt t_(b)` is

`12 t^(2) - t^(3)`

`24 -6t`

`24t - 6t^(2)`

`24 -= 6t - g`

Text Solution

Verified by Experts

Topper's Solved these Questions

RACE
ALLEN|Exercise RACE 19|6 Videos
RACE
ALLEN|Exercise Race 21|4 Videos
NEWTONS LAWS OF MOTION
ALLEN|Exercise EXERCISE-III|28 Videos
SIMPLE HARMONIC MOTION
ALLEN|Exercise Example|1 Videos

Similar Questions

Explore conceptually related problems

The XI^(th) class students of ALLEN designed a rocket. The rocket was launched from cycle stand of ALLEN straight up into the air. At t = 0 , the rocket is at y = 0 with V_(y) (t = 0) = 0 . The velocity of the rocket is given by: V_(y) = (24t - 3t^(2))m//s for 0 le t le t_(b) where t_(b) is the time at which fuel burns out. vertically upward direction is taken as positive. (g = 10m//s^(2)) The time taken for rocket to reach its maximum height is

The XI^(th) class students of ALLEN designed a rocket. The rocket was launched from cycle stand of ALLEN straight up into the air. At t = 0 , the rocket is at y = 0 with V_(y) (t = 0) = 0 . The velocity of the rocket is given by: V_(y) = (24t - 3t^(2))m//s for 0 le t le t_(b) where t_(b) is the time at which fuel burns out. vertically upward direction is taken as positive. (g = 10m//s^(2)) The displacement of the rocket till the fuel burns out (t = t_(b)) is

The slove of the normal to the curve given by x=f(t),y=g(t) at the point where t=t_(0) is

The acceleration of a particle is given as a = 3x^2 . At t = 0, v = 0, x = 0. The velocity at t = 2 sec will be-

The velocity of particle at time t is given by the relation v=6t-(t^(2))/(6) . The distance traveled in 3 s is, if s=0 at t=0

A rocket prototype is fired from ground at time t = 0 and it goes straight up. Take the launch point as origin and vertically upward direction as positive x direction. The acceleration of the rocket is given by a = (g)/(2) - kt^(2), 0 lt t le t_(0) =- g, t gt t_(0) Where t_(0) = sqrt((3g)/(2k)) (a) Find maximum velocity of the rocket during the up journey. (b) Find maximum height attained by the rocket. (c) Find total time of flight.

The velocity of a particle is given by v=v_(0) sin omegat , where v_(0) is constant and omega=2pi//T . Find the average velocity in time interval t=0 to t=T//2.

A particle starts moving rectilinearly at time t = 0 such that its velocity(v) changes with time (t) as per equation – v = (t2 – 2t) m//s for 0 lt t lt 2 s = (–t^(2) + 6t – 8) m//s for 2 le te 4 s (a) Find the interval of time between t = 0 and t = 4 s when particle is retarding. (b) Find the maximum speed of the particle in the interval 0 le t le 4 s .

(a) the displacement of a particle is given by s - a sin (omega t = kx) , where t is in second and x is in meter. Find the dimensions of omega and k . (b) The velocity of a praticle is given by v = v_(0) e^(-lambda t) , where t is time. Find the dimensions of v_(0) and lambda .

ALLEN-RACE-Basic Maths (Wave Motion & Dopplers Effect) (Stationary waves & doppler effect, beats)

The XI^(th) class students of ALLEN designed a rocket. The rocket was ...
Text Solution
|
The frequency of a radar is 780 MHz. After getting reflected from an a...
Text Solution
|
A locomotive approaching a crossing at a speed of 20 ms^(-1) sounds a ...
Text Solution
|
An aluminium rod having a length 100 cm is clamped at its middle point...
Text Solution
|
A column of air at 51^(@) C and a tuning fork produce 4 beats per seco...
Text Solution
|
A uniform string resonates with a tuning fork, at a maximum tension of...
Text Solution
|
If in a stationary wave the amplitude corresponding to antinode is 4 c...
Text Solution
|
What is the phase difference between the displacement wave and pressur...
Text Solution
|
A wire of length l having tension T and radius r vibrates with fundame...
Text Solution
|
Equation of a standing wave is generally expressed as y=2Asinomegatcos...
Text Solution
|
Two vibrating strings of same material stretched under same tension an...
Text Solution
|
The wave-function for a certain standing wave on a string fixed at bot...
Text Solution
|
In a standing transerse wave on a string :
Text Solution
|
A string vibrates in 5 segments to a frequency of 480 Hz. The frequen...
Text Solution
|
A 2.0m long string with a linear mass density of 5.2xx10^(-3) kg m^(-1...
Text Solution
|
A wave is given by the equation y = 10 sin 2 pi (100 t - 0.02 x) + ...
Text Solution
|
In case of closed organ pipe, which harmonin the p^(th) overtone will ...
Text Solution
|
An organ pipe of length L is open at one end and closed at other end. ...
Text Solution
|
The first resonance length of a resonance tube is 40 cm and the second...
Text Solution
|
A man sitting in a moving train hears the whistle of the engine. The f...
Text Solution
|
A whistle of frequency 500 Hz tied to the end of a string of length 1....
Text Solution
|