Volume 1
A light spring of force constant 8Nm^−1 is cut into two equal halves and the two are connected in parallel, the equivalent force constant of the system is
01
Nov
A light spring of force constant 8Nm^−1 is cut into two equal halves and the two are connected in parallel, the equivalent force constant of the system is A light spring of force constant 8Nm^−1 is cut into two equal halves and the two are connected in parallel the equivalent force constant of the system [...]
In a spring- mass system , the length of the spring is L, and it has a mass M attached to it and oscillates with an angular frequency ω. The spring is then cut into two parts, one (i) with relaxed length αL and the other (ii) with relaxed length (1−α) L. The force constants of the two spring A and B are
01
Nov
In a spring- mass system , the length of the spring is L, and it has a mass M attached to it and oscillates with an angular frequency ω. The spring is then cut into two parts, one (i) with relaxed length αL and the other (ii) with relaxed length (1−α) L. The force constants [...]
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and it has a mass M attached to it and oscillates with an angular frequency ω. The spring is then cut into two parts ,
In a spring- mass system ,
one (i) with relaxed length αL and the other (ii) with relaxed length (1−α) L. The force constants of the two spring A and B are ,
the length of the spring is L ,
Two particle are executing simple harmonic motion. At an instant of time t their displacement are y1=acos(ωt) and y2=asin(ωt) Then the phase difference between y1 and y2 is
01
Nov
Two particle are executing simple harmonic motion. At an instant of time t their displacement are y1=acos(ωt) and y2=asin(ωt) Then the phase difference between y1 and y2 is Two particle are executing simple harmonic motion. At an instant of time t their displacement are y1=acos(ωt) and y2=asin(ωt) Then the phase difference between y1 and y2 [...]
Lissajous figure obtained by combining x = a sin ⍵t and y = a sin (⍵t + π/4) will be
01
Nov
Lissajous figure obtained by combining x = a sin ⍵t and y = a sin (⍵t + π/4) will be Lissajous figure obtained by combining x = a sin ⍵t and y = a sin (⍵t + π/4) will be November 1, 2020 Category: Arihant Physics by D.C Pandey , Chapter 11 - SHM , [...]
In order that the resultant path on superimposing two mutually perpendicular SHM be a circle, the conditions are that
01
Nov
In order that the resultant path on superimposing two mutually perpendicular SHM be a circle, the conditions are that In order that the resultant path on superimposing two mutually perpendicular SHM be a circle the conditions are that November 1, 2020 Category: Arihant Physics by D.C Pandey , Chapter 11 - SHM , Volume 1 [...]
A body of mass 0.01 kg executes simple harmonic motion about x = 0 under the influence of a force as shown in figure. The period of SHM is
01
Nov
A body of mass 0.01 kg executes simple harmonic motion about x = 0 under the influence of a force as shown in figure. The period of SHM is A body of mass 0.01 kg executes simple harmonic motion about x = 0 under the influence of a force as shown in figure. The period [...]
The velocity-time diagram of a harmonic oscillator is shown in the adjoining figure. The frequency of oscillation is :
01
Nov
The velocity-time diagram of a harmonic oscillator is shown in the adjoining figure. The frequency of oscillation is : The velocity-time diagram of a harmonic oscillator is shown in the adjoining figure. The frequency of oscillation is : November 1, 2020 Category: Arihant Physics by D.C Pandey , Chapter 11 - SHM , Volume 1 [...]
The graph shows the variation of displacement of a particle executing S.H.M with time. We inference form this graph that.
01
Nov
The graph shows the variation of displacement of a particle executing S.H.M with time. We inference form this graph that. The graph shows the variation of displacement of a particle executing S.H.M with time. We inference form this graph that. November 1, 2020 Category: Arihant Physics by D.C Pandey , Chapter 11 - SHM , [...]
The displacement time graph of a particle executing S.H.M. is as shown in the figure. The corresponding force-time graph of the particle is:
01
Nov
The displacement time graph of a particle executing S.H.M. is as shown in the figure. The corresponding force-time graph of the particle is: The displacement time graph of a particle executing S.H.M. is as shown in the figure. The corresponding force-time graph of the particle is: November 1, 2020 Category: Arihant Physics by D.C Pandey [...]
The acceleration a of a particle undergoing S.H.M. is shown in the figure. Which of the labelled points corresponds to the particle being at -x
01
Nov
The acceleration a of a particle undergoing S.H.M. is shown in the figure. Which of the labelled points corresponds to the particle being at -x The acceleration a of a particle undergoing S.H.M. is shown in the figure. Which of the labelled points corresponds to the particle being at -x November 1, 2020 Category: Arihant [...]