Cengage NEET by C.P Singh

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A body executes SHM of period 3s under the influence of one force, and SHM of period 4s under the influence of a second force. When both the forces act simultaneously in the same direction, the period of oscillation will be
30
Oct
A body executes SHM of period 3s under the influence of one force, and SHM of period 4s under the influence of a second force. When both the forces act simultaneously in the same direction, the period of oscillation will be A body executes SHM of period 3s under the influence of one force and [...]
Posted in: Cengage NEET by C.P Singh , Chapter 13 - Simple Harmonic Motion , Part 1 ,
Tags: A body executes SHM of period 3s under the influence of one force , and SHM of period 4s under the influence of a second force. When both the forces act simultaneously in the same direction , the period of oscillation will be ,
The minimum phase difference between the two simple harmonic oscillations y1=1/2sinωt+(3–√/2)cosωt and y2=sinωt+cosωt is
30
Oct
The minimum phase difference between the two simple harmonic oscillations y1=1/2sinωt+(3–√/2)cosωt and y2=sinωt+cosωt is The minimum phase difference between the two simple harmonic oscillations y1=1/2sinωt+(3–√/2)cosωt and y2=sinωt+cosωt is 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: The minimum phase difference between the two simple harmonic oscillations y1=1/2sinωt+(3–√/2)cosωt and y2=sinωt+cosωt is ,
The ratio of the amplitude of the simple pendulum oscillation gives by y1 = A sin ωt and y2 = 2/A ​ sin ωt + 2/A ​cos ωt is
30
Oct
The ratio of the amplitude of the simple pendulum oscillation gives by y1 = A sin ωt and y2 = 2/A ​ sin ωt + 2/A ​cos ωt is The ratio of the amplitude of the simple pendulum oscillation gives by y1 = A sin ωt and y2 = 2/A ​ sin ωt + 2/A [...]
Posted in: Cengage NEET by C.P Singh , Chapter 13 - Simple Harmonic Motion , Part 1 ,
Tags: The ratio of the amplitude of the simple pendulum oscillation gives by y1 = A sin ωt and y2 = 2/A ​ sin ωt + 2/A ​cos ωt is ,
A particle moves on the X-axis is according to the equation x=A+B sin ωt. The motion is simple harmonic with amplitude:
30
Oct
A particle moves on the X-axis is according to the equation x=A+B sin ωt. The motion is simple harmonic with amplitude: The motion of a particle is given by x = A sin ωt + B cos ωt.The motion of the particle is October 30, 2020 Category: Cengage NEET by C.P Singh , Chapter 13 [...]
Posted in: Cengage NEET by C.P Singh , Chapter 13 - Simple Harmonic Motion , Part 1 ,
Tags: The motion of a particle is given by x = A sin ωt + B cos ωt.The motion of the particle is ,
The motion of a particle is given by x = A sin ωt + B cos ωt.The motion of the particle is
30
Oct
The motion of a particle is given by x = A sin ωt + B cos ωt.The motion of the particle is The motion of a particle is given by x = A sin ωt + B cos ωt.The motion of the particle is October 30, 2020 Category: Cengage NEET by C.P Singh , Chapter [...]
Posted in: Cengage NEET by C.P Singh , Chapter 13 - Simple Harmonic Motion , Part 1 ,
Tags: The motion of a particle is given by x = A sin ωt + B cos ωt.The motion of the particle is ,
In the figure, the vertical sections of the string are long. A is released from rest from the position shown. Then
30
Oct
In the figure, the vertical sections of the string are long. A is released from rest from the position shown. Then In the figure the vertical sections of the string are long. A is released from rest from the position shown. Then October 30, 2020 Category: Cengage NEET by C.P Singh , Chapter 13 - [...]
Posted in: Cengage NEET by C.P Singh , Chapter 13 - Simple Harmonic Motion , Part 1 ,
Tags: In the figure , the vertical sections of the string are long. A is released from rest from the position shown. Then ,
A uniform rod of length (L) and mass (M) is pivoted at the centre. Its two ends are attached to two springs of equal spring constants (k). The springs are fixed to rigid supports as shown in the figure, and the rod is free to oscillate in the horizontal plane. The rod is free to oscillate in the horizontal plane. The rod is gently pushed through a small angle (theta) in one direction and released. The frequency of oscillation is
30
Oct
A uniform rod of length (L) and mass (M) is pivoted at the centre. Its two ends are attached to two springs of equal spring constants (k). The springs are fixed to rigid supports as shown in the figure, and the rod is free to oscillate in the horizontal plane. The rod is free to [...]
Posted in: Cengage NEET by C.P Singh , Chapter 13 - Simple Harmonic Motion , Part 1 ,
Tags: A coin is placed on a horizontal platform , A mass M , attached to a horizontal spring , which undergoes vertical SHM of angular frequency ω. The amplitude of oscillation is gradually increased. The coin will leave contact with the platform for the first time ,
A mass M, attached to a horizontal spring, executes S.H.M. with amplitude A1. When the mass M passes through its mean position then a smaller mass m is placed over it and both of them move together with amplitude A2. The ratio of (A2/A1 ​) is :-
30
Oct
A mass M, attached to a horizontal spring, executes S.H.M. with amplitude A1. When the mass M passes through its mean position then a smaller mass m is placed over it and both of them move together with amplitude A2. The ratio of (A2/A1 ​) is :- A coin is placed on a horizontal platform [...]
Posted in: Cengage NEET by C.P Singh , Chapter 13 - Simple Harmonic Motion , Part 1 ,
Tags: A coin is placed on a horizontal platform , A mass M , attached to a horizontal spring , which undergoes vertical SHM of angular frequency ω. The amplitude of oscillation is gradually increased. The coin will leave contact with the platform for the first time ,
A coin is placed on a horizontal platform, which undergoes vertical SHM of angular frequency ω. The amplitude of oscillation is gradually increased. The coin will leave contact with the platform for the first time
30
Oct
A coin is placed on a horizontal platform, which undergoes vertical SHM of angular frequency ω. The amplitude of oscillation is gradually increased. The coin will leave contact with the platform for the first time A coin is placed on a horizontal platform which undergoes vertical SHM of angular frequency ω. The amplitude of oscillation [...]
Posted in: Cengage NEET by C.P Singh , Chapter 13 - Simple Harmonic Motion , Part 1 ,
Tags: A coin is placed on a horizontal platform , which undergoes vertical SHM of angular frequency ω. The amplitude of oscillation is gradually increased. The coin will leave contact with the platform for the first time ,
In the previous question, the angular frequency of the simple harmonic motion is ω. The coefficient of friction between the coin and the platform is μ. The amplitude of oscillation is gradually increased. The coin will begin to slip on the platform for the first time (i) at the extreme positions of oscillations (ii) at the mean position (iii) for an amplitude of μg/ω^2 (iv) for an amplitude of g/μω^2
30
Oct
In the previous question, the angular frequency of the simple harmonic motion is ω. The coefficient of friction between the coin and the platform is μ. The amplitude of oscillation is gradually increased. The coin will begin to slip on the platform for the first time (i) at the extreme positions of oscillations (ii) at [...]
Posted in: Cengage NEET by C.P Singh , Chapter 13 - Simple Harmonic Motion , Part 1 ,
Tags: A coin is placed on a horizontal platform , A person normally weighing 60kg stands on a platform which oscillates up and down simple harmonically with a frequency 2Hz and an amplitude 5cm. If a machine on the platform gives the person's weight , As shown in figure a simple harmonic motion oscillator having identical four springs has time period , In the previous question ,