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- Fourier Series
- Fourier Series
- Fourier Series Representation of Periodic Signals
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- Fourier Series Properties
- Properties of Continuous-Time Fourier Series
- Time Differentiation and Integration Properties of Continuous-Time Fourier Series
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- Wave Symmetry
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- Fourier Transform
- Fourier Transforms
- Fourier Transforms Properties
- Fourier Transform – Representation and Condition for Existence
- Properties of Continuous-Time Fourier Transform
- Table of Fourier Transform Pairs
- Linearity and Frequency Shifting Property of Fourier Transform
- Modulation Property of Fourier Transform
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- Frequency Derivative Property of Fourier Transform
- Parseval’s Theorem & Parseval’s Identity of Fourier Transform
- Fourier Transform of Complex and Real Functions
- Fourier Transform of a Gaussian Signal
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- Fourier Transform of the Sine and Cosine Functions
- Fourier Transform of Periodic Signals
- Conjugation and Autocorrelation Property of Fourier Transform
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- Analysis of LTI System with Fourier Transform
- Relation between Discrete-Time Fourier Transform and Z Transform
- Convolution and Correlation
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- System Bandwidth vs Signal Bandwidth
- Time Convolution Theorem
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- Energy Spectral Density and Autocorrelation Function
- Autocorrelation Function of a Signal
- Cross Correlation Function and its Properties
- Detection of Periodic Signals in the Presence of Noise (by Autocorrelation)
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- Autocorrelation Function and its Properties
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- Sampling
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- Laplace Transform
- Laplace Transforms
- Common Laplace Transform Pairs
- Laplace Transform of Unit Impulse Function and Unit Step Function
- Laplace Transform of Sine and Cosine Functions
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- Laplace Transform of Damped Sine and Cosine Functions
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- Laplace Transform of Periodic Functions
- Laplace Transform of Rectifier Function
- Laplace Transforms Properties
- Linearity Property of Laplace Transform
- Time Shifting Property of Laplace Transform
- Time Scaling and Frequency Shifting Properties of Laplace Transform
- Time Differentiation Property of Laplace Transform
- Time Integration Property of Laplace Transform
- Time Convolution and Multiplication Properties of Laplace Transform
- Initial Value Theorem of Laplace Transform
- Final Value Theorem of Laplace Transform
- Parseval's Theorem for Laplace Transform
- Laplace Transform and Region of Convergence for right sided and left sided signals
- Laplace Transform and Region of Convergence of Two Sided and Finite Duration Signals
- Circuit Analysis with Laplace Transform
- Step Response and Impulse Response of Series RL Circuit using Laplace Transform
- Step Response and Impulse Response of Series RC Circuit using Laplace Transform
- Step Response of Series RLC Circuit using Laplace Transform
- Solving Differential Equations with Laplace Transform
- Difference between Laplace Transform and Fourier Transform
- Difference between Z Transform and Laplace Transform
- Relation between Laplace Transform and Z-Transform
- Relation between Laplace Transform and Fourier Transform
- Laplace Transform – Time Reversal, Conjugation, and Conjugate Symmetry Properties
- Laplace Transform – Differentiation in s Domain
- Laplace Transform – Conditions for Existence, Region of Convergence, Merits & Demerits
- Z Transform
- Z-Transforms (ZT)
- Common Z-Transform Pairs
- Z-Transform of Unit Impulse, Unit Step, and Unit Ramp Functions
- Z-Transform of Sine and Cosine Signals
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- Z-Transforms Properties
- Properties of ROC of the Z-Transform
- Z-Transform and ROC of Finite Duration Sequences
- Conjugation and Accumulation Properties of Z-Transform
- Time Shifting Property of Z Transform
- Time Reversal Property of Z Transform
- Time Expansion Property of Z Transform
- Differentiation in z Domain Property of Z Transform
- Initial Value Theorem of Z-Transform
- Final Value Theorem of Z Transform
- Solution of Difference Equations Using Z Transform
- Long Division Method to Find Inverse Z Transform
- Partial Fraction Expansion Method for Inverse Z-Transform
- What is Inverse Z Transform?
- Inverse Z-Transform by Convolution Method
- Transform Analysis of LTI Systems using Z-Transform
- Convolution Property of Z Transform
- Correlation Property of Z Transform
- Multiplication by Exponential Sequence Property of Z Transform
- Multiplication Property of Z Transform
- Residue Method to Calculate Inverse Z Transform
- System Realization
- Cascade Form Realization of Continuous-Time Systems
- Direct Form-I Realization of Continuous-Time Systems
- Direct Form-II Realization of Continuous-Time Systems
- Parallel Form Realization of Continuous-Time Systems
- Causality and Paley Wiener Criterion for Physical Realization
- Discrete Fourier Transform
- Discrete-Time Fourier Transform
- Properties of Discrete Time Fourier Transform
- Linearity, Periodicity, and Symmetry Properties of Discrete-Time Fourier Transform
- Time Shifting and Frequency Shifting Properties of Discrete Time Fourier Transform
- Inverse Discrete-Time Fourier Transform
- Time Convolution and Frequency Convolution Properties of Discrete-Time Fourier Transform
- Differentiation in Frequency Domain Property of Discrete Time Fourier Transform
- Parseval’s Power Theorem
- Miscellaneous Concepts
- What is Mean Square Error?
- What is Fourier Spectrum?
- Region of Convergence
- Hilbert Transform
- Properties of Hilbert Transform
- Symmetric Impulse Response of Linear-Phase System
- Filter Characteristics of Linear Systems
- Characteristics of an Ideal Filter (LPF, HPF, BPF, and BRF)
- Zero Order Hold and its Transfer Function
- What is Ideal Reconstruction Filter?
- What is the Frequency Response of Discrete Time Systems?
- Basic Elements to Construct the Block Diagram of Continuous Time Systems
- BIBO Stability Criterion
- BIBO Stability of Discrete-Time Systems
- Distortion Less Transmission
- Distortionless Transmission through a System
- Rayleigh’s Energy Theorem
Laplace Transform of Periodic Functions (Time Periodicity Property of Laplace Transform)
Laplace Transform
The Laplace transform is a mathematical tool which is used to convert the differential equation in time domain into the algebraic equations in the frequency domain or s-domain.
Mathematically, if x(t) is a time domain function, then its Laplace transform is defined as,
$$\mathrm{L[x(t)]\:=\:X(s)\:=\:\int_{-\infty}^{\infty}\:x(t)e^{-st}\:dt\:\:\dotso\:(1)}$$
Equation (1) gives the bilateral Laplace transform of the function x(t). But for the causal signals, the unilateral Laplace transform is applied, which is defined as,
$$\mathrm{L[x(t)]\:=\:X(s)\:=\:\int_{0}^{\infty}\:x(t)e^{-st}\:dt\:\:\dotso\:(2)}$$
Laplace Transform of Periodic Functions
The Laplace transform of periodic functions can be determined by using the time shifting property $\mathrm{[\text{i.e, }x(t \:-\: T)\:=\:e^{sT}\:X(s)]}$. Consider a causal periodic function x(t) which satisfies the condition $\mathrm{x(t)\:=\:x(t\:+\:nT)}$ or all t > 0, where T is the time period of x(t) and n = 0, 1, 2,....
Now, from the definition of Laplace transform, we have,
$$\mathrm{L[x(t)] \:=\: X(s) \:=\: \int_{0}^{\infty}\: x(t) e^{-st} \: dt \quad \dotso\: (3)}$$
The above expression can also be written as,
$$\mathrm{X(s) \:=\: \int_{0}^{T}\: x(t)\: e^{-st} \: dt \:+\: \int_{T}^{2T}\: x(t) e^{-st} \: dt \:+\: \int_{2T}^{3T}\: x(t) e^{-st} \: dt \:+\: \dotso \:+\:\int_{nT}^{(n+1)T}\: x(t)\:e^{-st}\:dt\:+\:\dotso}$$
$$\mathrm{\Rightarrow\: X(s) \:=\: \int_{0}^{T}\: x(t) e^{-st} \: dt \:+\: e^{-sT} \int_{0}^{T}\: x(t\:+\:T) e^{-st} \: dt\:+\: e^{-2sT} \int_{0}^{T}\: x(t\:+\:2T) e^{-st} \: dt \:+\: \dotso\:+\: e^{-nsT} \int_{0}^{T}\: x(t\:+\:nT) e^{-st} \: dt \:+\: \dotso \quad \dots (4)}$$
As the function x(t) is a periodic function, therefore,
$$\mathrm{x(t) \:=\:x(t\:+\:T)\:=\:x(t\:+\:2T)\:=\:\dotso}$$
Hence, the equation (4) can be written as
$$\mathrm{X(s) \:=\: \int_{0}^{T}\: x(t) e^{-st} \: dt \:+\: e^{-sT} \int_{0}^{T}\: x(t) e^{-st} \: dt \:+\: e^{-2sT} \int_{0}^{T}\: x(t) e^{-st} \: dt \:+\: \dotso \:+\: e^{-nsT} \int_{0}^{T}\: x(t) e^{-st} \: dt \:+\: \dotso}$$
$$\mathrm{\Rightarrow\: X(s) \:=\: \left[ 1 \:+\: e^{-sT} \:+\: e^{-2sT} \:+\: \dotso \:+\: e^{-nsT} \:+\: \dotso \right]\: \int_{0}^{T}\: x(t) e^{-st} \: dt \quad \dotso\: (5)}$$
Using the binomial series expansion, we can write,
$$\mathrm{X(s) \:=\: \left[1 \:-\: e^{-sT} \right]^{-1}\: \int_{0}^{T}\: x(t) e^{-st} \: dt}$$
$$\mathrm{\therefore \: X(s) \:=\: \frac{1}{1 \:-\: e^{-sT}}\: X_1(s) \quad \dotso\: (6)}$$
Where,
$$\mathrm{X_1(s)\:=\:\int_{0}^{T}\:x(t)\:e^{-st}\:dt\:\:\dotso\:(7)}$$
The $\mathrm{X_1(s)}$ is the Laplace transform of the first period of the time function. The eqn. (6) represents the periodicity property of the Laplace transform.
Numerical Example
Find the Laplace transform of function $\mathrm{x(t)\:=\:sin\pi t\:u(t)}$ using periodicity property of Laplace transform.
Solution
The given function is,
$$\mathrm{x(t)\:=\:sin\:\pi t\:u(t)}$$
The given signal is a periodic signal with a time period of T which is given by,
$$\mathrm{T \:=\: \frac{2\pi}{\omega} \:=\: \frac{2\pi}{\pi}\:=\:2sec}$$
Now, by using the periodicity property of Laplace transform, we have,
$$\mathrm{L[x(t)] \:=\: X(s) \:=\: \frac{1}{[1âe^{â2s}]}\:\int^{2}_{0}\:sin(\pi t)e^{âst}\:dt}$$
$$\mathrm{\Rightarrow\: X(s) \:=\: \frac{1}{1 \:-\: e^{-2s}}\: \int_{0}^{2}\: \left( \frac{e^{j\pi t} \:-\: e^{-j\pi t}}{2j} \right) e^{-st} \: dt}$$
$$\mathrm{\Rightarrow\: X(s) \:=\: \frac{1}{1 \:-\: e^{-2s}}\: \left[ \frac{1}{2j} \left( \int_{0}^{2}\: e^{j\pi t} e^{-st} \: dt \:-\: \int_{0}^{2}\: e^{-j\pi t} e^{-st} \: dt \right) \right]}$$
$$\mathrm{\Rightarrow\: X(s) \:=\: \frac{1}{1 \:-\: e^{-2s}}\: \left[ \frac{1}{2j} \left( \int_{0}^{2}\: e^{-(s \:-\: j\pi) t} \: dt \:-\: \int_{0}^{2}\: e^{-(s \:+\: j\pi) t} \: dt \right) \right]}$$
$$\mathrm{\Rightarrow \:X(s) \:=\: \frac{1}{1 \:-\: e^{-2s}}\: \left\{ \frac{1}{2j} \left[ \frac{e^{-(s \:-\: j\pi) t}}{-(s \:-\: j\pi)} \:-\: \frac{e^{-(s \:+\: j\pi) t}}{-(s \:+\: j\pi)} \right]_{0}^{2} \right\}}$$
On solving the limits, we get,
$$\mathrm{X(s) \:=\: \frac{1}{1 \:-\: e^{-2s}} \left\{ \frac{1}{2j} \left[ \frac{-(s \:+\: j\pi) \left( e^{-2(s \:-\: j\pi)t} \:-\: 1 \right) \:+\: (s \:-\: j\pi) \left( e^{-2(s \:+\: j\pi)t} \:-\: 1 \right)}{s^2 \:+\: \pi^2} \right] \right\}}$$
$$\mathrm{\Rightarrow\: X(s) \:=\: \frac{1}{1 \:-\: e^{-2s}} \left[ \frac{\pi (1 \:-\: e^{-2s})}{s^2 \:+\: \pi^2} \right]}$$
$$\mathrm{\therefore\: X(s) \:=\: \frac{\pi}{s^2 \:+\: \pi^2}}$$