Chapter 13 – Simple Harmonic Motion

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A point mass is subjected to two simultaneous sinusoidal displacements in x−direction,x1(t)= A sin (ω)t and x2(t) = A sin(ωt+2π/3). Adding a third sinusoidal displacement x3(t)=Bsin(ωt+ϕ) brings the mas to a complete rest. The values of (B) and (phi) are.
30
Oct
A point mass is subjected to two simultaneous sinusoidal displacements in x−direction,x1(t)= A sin (ω)t and x2(t) = A sin(ωt+2π/3). Adding a third sinusoidal displacement x3(t)=Bsin(ωt+ϕ) brings the mas to a complete rest. The values of (B) and (phi) are. A point mass is subjected to two simultaneous sinusoidal displacements in x−direction x1(t)= A sin [...]
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Tags: A point mass is subjected to two simultaneous sinusoidal displacements in x−direction , x1(t)= A sin (ω)t and x2(t) = A sin(ωt+2π/3). Adding a third sinusoidal displacement x3(t)=Bsin(ωt+ϕ) brings the mas to a complete rest. The values of (B) and (phi) are. ,
A particle moves in the x−y the according to the equation, r=(iˆ+2jˆ)Acosωt. The motion of the particle is 1. on a straight line 2. on an ellipse 3. periodic 4. simple harmonic
30
Oct
A particle moves in the x−y the according to the equation, r=(iˆ+2jˆ)Acosωt. The motion of the particle is 1. on a straight line 2. on an ellipse 3. periodic 4. simple harmonic A particle moves in the x−y the according to the equation r=(iˆ+2jˆ)Acosωt. The motion of the particle is 1. on a straight line [...]
Posted in: Cengage NEET by C.P Singh , Chapter 13 - Simple Harmonic Motion , Part 1 ,
Tags: A particle moves in the x−y the according to the equation , r=(iˆ+2jˆ)Acosωt. The motion of the particle is 1. on a straight line 2. on an ellipse 3. periodic 4. simple harmonic ,
A particle moves on the X-axis according to the equation x=x0sin^2ωt. The motion simple harmonic
30
Oct
A particle moves on the X-axis according to the equation x=x0sin^2ωt. The motion simple harmonic A particle moves on the X-axis according to the equation x=x0sin^2ωt. The motion simple harmonic October 30, 2020 Category: Cengage NEET by C.P Singh , Chapter 13 - Simple Harmonic Motion , Part 1 ,
Posted in: Cengage NEET by C.P Singh , Chapter 13 - Simple Harmonic Motion , Part 1 ,
Tags: A particle moves on the X-axis according to the equation x=x0sin^2ωt. The motion simple harmonic ,
The displacement equation of a particle is x = 3sin2t + 4cos2t. The amplitude and maximum velocity will be respectively
30
Oct
The displacement equation of a particle is x = 3sin2t + 4cos2t. The amplitude and maximum velocity will be respectively The displacement equation of a particle is x = 3sin2t + 4cos2t. The amplitude and maximum velocity will be respectively October 30, 2020 Category: Cengage NEET by C.P Singh , Chapter 13 - Simple Harmonic [...]
Posted in: Cengage NEET by C.P Singh , Chapter 13 - Simple Harmonic Motion , Part 1 ,
Tags: The displacement equation of a particle is x = 3sin2t + 4cos2t. The amplitude and maximum velocity will be respectively ,
A disc of radius R and mass M is pivoted at the rim and it set for small oscillations. If simple pendulum has to have the same period as that of the disc, the length of the simple pendulum should be
30
Oct
A disc of radius R and mass M is pivoted at the rim and it set for small oscillations. If simple pendulum has to have the same period as that of the disc, the length of the simple pendulum should be A disc of radius R and mass M is pivoted at the rim and [...]
Posted in: Cengage NEET by C.P Singh , Chapter 13 - Simple Harmonic Motion , Part 1 ,
Tags: A disc of radius R and mass M is pivoted at the rim and it set for small oscillations. If simple pendulum has to have the same period as that of the disc , the length of the simple pendulum should be ,
Two pendulum of lengths 1m and 16m are in phase at the mean position at a certain instant of time. If T is the time period of the shorter pendulum, then the minimum time after which they will again be in phase is
30
Oct
Two pendulum of lengths 1m and 16m are in phase at the mean position at a certain instant of time. If T is the time period of the shorter pendulum, then the minimum time after which they will again be in phase is then the minimum time after which they will again be in phase [...]
Posted in: Cengage NEET by C.P Singh , Chapter 13 - Simple Harmonic Motion , Part 1 ,
Tags: then the minimum time after which they will again be in phase is , Two pendulum of lengths 1m and 16m are in phase at the mean position at a certain instant of time. If T is the time period of the shorter pendulum ,
Two particles execute SHM of the same time period along the same straight lines. They cross each other at the mean position while going in opposite directions. Their phase difference is
30
Oct
Two particles execute SHM of the same time period along the same straight lines. They cross each other at the mean position while going in opposite directions. Their phase difference is Two particles execute SHM of the same time period along the same straight lines. They cross each other at the mean position while going [...]
Posted in: Cengage NEET by C.P Singh , Chapter 13 - Simple Harmonic Motion , Part 1 ,
Tags: Two particles execute SHM of the same time period along the same straight lines. They cross each other at the mean position while going in opposite directions. Their phase difference is ,
Two simple pendulums whose lengths are 100cm and 121cm are suspended side by side. their bobs are pulled together and then released. After how many minimum oscillation of the longer pendulum will the two be in phase again
30
Oct
Two simple pendulums whose lengths are 100cm and 121cm are suspended side by side. their bobs are pulled together and then released. After how many minimum oscillation of the longer pendulum will the two be in phase again Two particles A and B execute simple harmonic motions of periods T and 5T / 4. They [...]
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Tags: Two particles A and B execute simple harmonic motions of periods T and 5T / 4. They start from mean position. The phase difference between them when the particle A complete one oscillation will be: ,
Two particles A and B execute simple harmonic motions of periods T and 5T / 4. They start from mean position. The phase difference between them when the particle A complete one oscillation will be:
30
Oct
Two particles A and B execute simple harmonic motions of periods T and 5T / 4. They start from mean position. The phase difference between them when the particle A complete one oscillation will be: Two particles A and B execute simple harmonic motions of periods T and 5T / 4. They start from mean [...]
Posted in: Cengage NEET by C.P Singh , Chapter 13 - Simple Harmonic Motion , Part 1 ,
Tags: Two particles A and B execute simple harmonic motions of periods T and 5T / 4. They start from mean position. The phase difference between them when the particle A complete one oscillation will be: ,
Electrons in an oscilloscope are deflected by two mutually perpendicular oscillating electric field such that at any time the displacement due to them are given by x=Acosωt, y=Asin(ωt+π/6). Then the path of the electron is
30
Oct
Electrons in an oscilloscope are deflected by two mutually perpendicular oscillating electric field such that at any time the displacement due to them are given by x=Acosωt, y=Asin(ωt+π/6). Then the path of the electron is Electrons in an oscilloscope are deflected by two mutually perpendicular oscillating electric field such that at any time the displacement [...]
Posted in: Cengage NEET by C.P Singh , Chapter 13 - Simple Harmonic Motion , Part 1 ,
Tags: Electrons in an oscilloscope are deflected by two mutually perpendicular oscillating electric field such that at any time the displacement due to them are given by x=Acosωt , y=Asin(ωt+π/6). Then the path of the electron is ,