In the arrangement shown in figure, pulleys are light and spring are ideal. `K_(1)`, `k_(2)`, `k_(3)`and `k_(4)` are force constant of the spring. Calculate period of small vertical oscillations of block of mass `m`.

In the arrangement shown in the diagram, pulleys are small and springs are ideal. k_(1)=k_(2)=k_(3)=k_(4)=10Nm^(-1) are force constants of the springs and mass m=10kg. If the time period of small vertical oscillations of the block of mass m is given by 2pix seconds, then find the value of x.

In the arrangement shown in the diagram, pulleys are small and springs are ideal. k_(1)=k_(2)=k_(3)=k_(4)=10Nm^(-1) are force constants of the springs and mass m=10kg. If the time period of small vertical oscillations of the block of mass m is given by 2pix seconds, then find the value of x.

In the arrangement shown if Fig. Pulleys are small and lught and spring are ideal and K_1=25(pi^2)(N)/(m) , K_2=2K_1 , K_3= and K_4=4K_1 are the force constant of the spring. Calculate the period of small vertical oscillation of block of mass m=3kg .

In the arrangement shown if Fig. Pulleys are small and lught and spring are ideal and K_1=25(pi^2)(N)/(m) , K_2=2K_1 , K_3= and K_4=4K_1 are the force constant of the spring. Calculate the period of small vertical oscillation of block of mass m=3kg .

Two spring of spring constants k_(1) and k_(2) ar joined and are connected to a mass m as shown in the figure. Calculate the frequency of oscillation of mass m.

There is a system of infinite pulleys and springs.Spring constants are in GP as k 2k 4k 8k.........oo as shown in the figure.All the pulleys are massless frictionless and strings are massless and inextensible.Then time period of small oscillations of the block will be (Mass of block is m ). qquad (in ) (i) 2

In the situation as shown in figure time period of small vertical oscillation of block will be - (String, springs and pulley are ideal)

In the situation as shown in figure time period of small vertical oscillation of block will be - (String, springs and pulley are ideal)

As shown in the figure, two light springs of force constant k_(1) and k_(2) oscillate a block of mass m. Its effective force constant will be