When a mass m is connected individually to two spring `S_(1)` and `S_(2)` , the oscillation frequencies are `v_(1) and v_(2)`. If the same mass is attached to the two springs as shwon in figure., the oscillation frequecy would be

When a mass m is connected individually to two springs S_(1) and S_(2) , the oscillation frequencies are v_(1) and v_(2) . If the same mass is attached to the two springs as shown in figure, the oscillation frequency would be

When a mass m is connected individually to two springs S_(1) and S_2 , the oscillation frequencies are upsilon_(1) and upsilon_(2) . If the same mass is attached to the two springs as shown in figure, the oscillation frequency would be

Two masses m_(1) and m_(2) are attached to a spring balance S as shown in figure. m_(1) gt m_(2) then the reading of spring balance will be . .

A mass is suspended separately by two springs of spring constants k_(1) and k_(2) in successive order. The time periods of oscillations in the two cases are T_(1) and T_(2) respectively. If the same mass be suspended by connecting the two springs in parallel, (as shown in figure) then the time period of oscillations is T. The correct relations is

S_(1) and S_(2) are two identical springs. The oscillation frequency is f. If one springs is removed, frequency will be

A particle of mass m is attached to three identical springs of spring constant k as shwon in figure. The time period of vertical oscillation of the particle is

In figure S_(1) and S_(1) are identical springs. The oscillation frequency of the mass m is f . if one spring is removed, the frequency will become

Calculate the period of oscillations of block of mass m attached with a set of springs as shown