Laplace Transform of Periodic Functions

Definition

A function $f(t)$ is said to be periodic with period $T > 0$ if $f(t + T) = f(t)$ for all $t \geq 0$. The Laplace transform of such a function simplifies the infinite integral calculation by focusing on a single period of the wave.

Main Content

1. The Periodic Property

A periodic function repeats its values at regular intervals (the period $T$).
Because the function repeats, the Laplace integral $\int_0^\infty e^{-st} f(t) dt$ can be decomposed into an infinite sum of integrals over each cycle $[nT, (n+1)T]$.

2. The Master Formula

The Laplace transform of a periodic function is given by the formula: $\mathcal{L}{f(t)} = \frac{1}{1 - e^{-sT}} \int_0^T e^{-st} f(t) dt$.
This formula allows us to compute the transform of complex repetitive waveforms by only integrating over the first period.

3. Visualizing Periodicity

Consider a square wave or a sawtooth wave that repeats every $T$ seconds.

f(t)
 ^
 |  |  |  |
 |  |  |  |
 +--+--+--+--> t
 0  T 2T 3T

The above diagram shows a periodic pulse train where the shape between $0$ and $T$ is identical to the shape between $T$ and $2T$.

Working / Process

1. Identify Parameters

Determine the period $T$ by observing the smallest interval after which the function repeats.
Extract the expression for $f(t)$ specifically for the interval $0 \leq t < T$.

2. Compute the Integral

Perform the definite integration: $I = \int_0^T e^{-st} f(t) dt$.
Use integration by parts or standard table lookups if the function $f(t)$ within the interval is complex.

3. Apply the Periodic Factor

Multiply the result of the integral by the periodic scaling factor $\frac{1}{1 - e^{-sT}}$.
Simplify the final algebraic expression in terms of $s$.

Advantages / Applications

Circuit Analysis: Used to analyze steady-state responses of electrical circuits subjected to periodic voltage sources (like AC signals).
Signal Processing: Essential for filtering periodic noise and understanding frequency components of waveforms.
Computational Efficiency: It eliminates the need to perform infinite integration, reducing complex problems to a single cycle calculation.

Summary

The Laplace transform of a periodic function is a powerful mathematical tool that converts a repeating signal into an algebraic function of the complex frequency $s$. By integrating over only one period $T$ and dividing by $(1 - e^{-sT})$, we characterize the entire infinite lifespan of the periodic function. Key terms include the period $T$, the periodic scaling factor, and the complex frequency $s$.