Oscillations – Definition of Periodic Time “The time taken by a particle to complete one full oscillation is called the periodic time.” Evaluate this statement.

Introduction / Context:
Oscillations occur in mechanical, electrical, and structural systems. Consistent terminology helps compare behaviors such as frequency, period, and phase across domains. This item checks the definition of “periodic time.”

Given Data / Assumptions:

• A system exhibiting repeated motion over time (oscillation/rotation/vibration).
• The motion is periodic (repeats identical states at regular intervals).

Concept / Approach:
Periodic time, usually denoted T, is the duration for one complete cycle after which the system repeats its state (position, velocity, etc.). The reciprocal quantity is frequency f, with the relation f = 1 / T, and for angular frequency ω, we have ω = 2π f = 2π / T.

Step-by-Step Solution:
Define: Periodic time T = time for one full oscillation. Frequency: f = number of oscillations per second; f = 1 / T. Angular frequency: ω = 2π f ⇒ T = 2π / ω. Hence the given statement matches the standard definition.

Verification / Alternative check:
In simple harmonic motion x(t) = A cos(ω t + φ), the motion repeats when ω t increases by 2π, so T = 2π / ω, which is the time for one complete oscillation.

Why Other Options Are Wrong:
Disagree: contradicts standard textbooks. Limiting to “small amplitudes” or “only for SHM” is unnecessary; the definition of period applies to any periodic motion. Requiring zero damping is incorrect; lightly damped systems can still be nearly periodic with a well-defined period (strictly, perfectly periodic if strictly undamped), but the definition of T remains the “time per cycle.”

Common Pitfalls:
Confusing period T with phase or amplitude; they are independent quantities.

Final Answer:
Agree