The position of a particle in motion is ...

The position of a particle in motion is given by `y = Csinomegat + Dcosomegat w.r.t` origin. Then motion of the particle is

A

`SHM` with amplitude `C+D`

B

`SHM` with amplitude `sqrt(C^(2) + D^(2))`

C

`SHM` with amplitude `((C + D))/(2)`

D

not `SHM`

Text Solution

Verified by Experts

The correct Answer is:

B

Topper's Solved these Questions

SIMPLE HARMONIC MOTION
RESONANCE|Exercise Exercise- 2, PART - I|26 Videos
SIMPLE HARMONIC MOTION
RESONANCE|Exercise Exercise- 2, PART - II|1 Videos
SIMPLE HARMONIC MOTION
RESONANCE|Exercise Exercise- 1, PART - I|25 Videos
SEMICONDUCTORS
RESONANCE|Exercise Exercise 3|88 Videos
TEST PAPERS
RESONANCE|Exercise FST-3|30 Videos

Similar Questions

Explore conceptually related problems

The motion of a particle is given by x = A sin omega t + B os omega t . The motion of the particle is

The motion of a particle is given by x=A sin omegat+Bcos omegat . The motion of the particle is

The motion of a particle is given x = A sin omega t + B cos omega t The motion of the particle is

The position vector of a particle moving in x-y plane is given by vec(r) = (A sinomegat)hat(i) + (A cosomegat)hat(j) then motion of the particle is :

The displacement of a particle is given by vecr=A(vecicosomegt+vecjsinomegat) . The motion of the particle is

The displacement of a particle along the x- axis it given by x = a sin^(2) omega t The motion of the particle corresponds to

The displacement of a particle is given by r=A(haticosomegat+hatjsinomegat) . The motion of the particle is

A particle move along y-axis according to equation y +3+4 cos omega t . The motion of the particle is

A x and y co-ordinates of a particle are x=A sin (omega t) and y = A sin(omegat + pi//2) . Then, the motion of the particle is

RESONANCE-SIMPLE HARMONIC MOTION -Exercise- 1, PART - II

The position of a particle in motion is given by y = Csinomegat + Dcos...
Text Solution
|
According to a scientists, he applied a force F = -cx^(1//3) on a part...
Text Solution
|
A particle performing SHM takes time equal to T (time period of SHM) i...
Text Solution
|
A particle executing linear SHM. Its time period is equal to the small...
Text Solution
|
If overset(vec)(F) is force vector, overset(vec)(v) is velocity , over...
Text Solution
|
Two SHM's are represented by y = a sin (omegat - kx) and y = b cos (om...
Text Solution
|
How long after the beginning of motion is the displacment of a harmoni...
Text Solution
|
The magnitude of average accleration in half time period in a simple h...
Text Solution
|
A particle moves on y-axis according to the equation y = A +B sin omeg...
Text Solution
|
Two particles execute SHMs of the same amplitude and frequency along t...
Text Solution
|
A mass M is performing linear simple harmonic motion. Then correct gra...
Text Solution
|
A body executing SHM passes through its equilibrium. At this instant, ...
Text Solution
|
The KE and PE , at is a particle executing SHM with amplitude A will b...
Text Solution
|
A point particle if mass 0.1 kg is executing SHM of amplitude 0.1 m. W...
Text Solution
|
For a particle performing SHM
Text Solution
|
Acceleration a versus time t graph of a body in SHM is given by a curv...
Text Solution
|
A particle performs SHM of amplitude A along a straight line. When it ...
Text Solution
|
Two springs, of spring constants k(1) and K(2), have equal highest vel...
Text Solution
|
A toy car of mass m is having two similar rubber ribbons attached to i...
Text Solution
|
A mass of 1 kg attached to the bottom of a spring has a certain freque...
Text Solution
|
A ball of mass m kg hangs from a spring of spring constant k. The bal...
Text Solution
|