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NO,oscillation is not necessarily a wave because energy is not transported in oscillation.In oscillation there is no space periodicity.An oscillation is periodic in time only where as a wave is periodic in time and space both.
Mass doesn't effect time, energy effects mass (proportional) and velocity effects time (not proportional).
The inverse of frequency.
The value of gravitational acceleration 'g' is totally unaffected by changing mass of the body. We are not talking about weight of the pendulum. It is the value 'g' we are talking about, which remains unaffected by changing mass as: g= ((2xpie)2)xL)/T2 where, g= gravitational acceleration L= length of simple pendulum T= time period in which the pendulum completes its single vibration or oscillation
Any oscillation in which the amplitude of the oscillating quantity decreases with time is referred as damped oscillation. Also known as damped vibration, http://www.answers.com/topic/damped-harmonic-motion
Mass oscillation time period = 2 pi sq rt. (m/k) Pendulum oscillation time period = 2 pi sq rt. (l/g)
NO,oscillation is not necessarily a wave because energy is not transported in oscillation.In oscillation there is no space periodicity.An oscillation is periodic in time only where as a wave is periodic in time and space both.
Mass doesn't effect time, energy effects mass (proportional) and velocity effects time (not proportional).
For a simple pendulum, consisting of a heavy mass suspended by a string with virtually no mass, and a small angle of oscillation, only the length of the pendulum and the force of gravity affect its period. t = 2*pi*sqrt(l/g) where t = time, l = length and g = acceleration due to gravity.
The inverse of frequency.
We could reduce random errors by taking the average of the time taken for one oscillation.
The value of gravitational acceleration 'g' is totally unaffected by changing mass of the body. We are not talking about weight of the pendulum. It is the value 'g' we are talking about, which remains unaffected by changing mass as: g= ((2xpie)2)xL)/T2 where, g= gravitational acceleration L= length of simple pendulum T= time period in which the pendulum completes its single vibration or oscillation
Any oscillation in which the amplitude of the oscillating quantity decreases with time is referred as damped oscillation. Also known as damped vibration, http://www.answers.com/topic/damped-harmonic-motion
Time period per oscillation=32/ 20=1.6 sec per oscillation.
time period
When viewing it the objec . Changes shape
time taken by pendulum/to complete 1 oscillation