Calculate the frequency of oscillations of a mass m = 10 kg in the following arangement of springs. (Given `k_(1) = k_(2) = k_(3) = k_(4) = k = 3` N/m)

Two springs of force constants k_(1) and k_(2) are joined together and the combination is attached to a mass m resting on a frictionless table at one end and clamped to a fixed support at the other. Show the frequency of oscillation of the mass is f = 1/(2pi)sqrt((k_(1)k_(2))/((k_(1) + k-(2)))m [Hint: Let the mass be displaced by x and the clamped end of the second spring by x^(') . Then mf = -k_(1)(x-x^(')) . Considering the first spring and the mass as a single system we have mf = -k_(2)x^(') ]

If the angular frequency of small oscillations of a thin uniform vertical rod of mass m and length l hinged at the point O (Fig.) is sqrt((n)/(l)) , then find n . The force constant for each spring is K//2 and take K = (2mg)/(l) . The springs are of negiligible mass. (g = 10 m//s^(2))

If the angular frequency of small oscillations of a thin uniform vertical rod of mass m and length l hinged at the point O (Fig.) is sqrt((n)/(l)) , then find n . The force constant for each spring is K//2 and take K = (2mg)/(l) . The springs are of negiligible mass. (g = 10 m//s^(2))

Calculate the concentration of all species of significant concentrations presents in 0.1 M H_(3)PO_(4) solution. ltbrlt K_(1) = 7.5 xx 10^(-3), K_(2) = 6.2 xx 10^(-8), K_(#) = 3.6 xx 10^(-13)

The figure shows a mass M attached to a series arrangement of two springs of spring constants k_(1) and k_(2) where k_(2) = 2k_(1) . If the mass M oscillates in simple harmonic motion with amplitude A, the amplitude of the point O is (alphaA)/(beta) . Find beta-alpha .

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 .

Two springs of force constants k_(1) and k_(2) , are connected to a mass m as shown. The frequency of oscillation of the mass is f . If both k_(1) and k_(2) are made four times their original values, the frequency of oscillation becomes

Springs of spring constant k, 2k, 4k , 8k, …. Are connected in series. A block of mass 50 kg is attached to the lower end of the last spring and the system is set into oscillation. If k = 3.0 N/cm, what is the time period of oscillations ?

Two springs, of force constants k_(1) and k_(2) , are connected to a mass ma as shown. The frequency of oscillation of mass is f . If both k_(1) and k_(2) are made four times their original values, the frequency of oscillation becomes