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Introduction - Principles of Signals and Systems - Prof. Aditya K. Jagannatham

Principles of Signals and Systems- Introduction to Signals and Systems, Signal Classification

Analog and Digital Signals

Energy and Power Signals

Real Exponential Signals

Memory/Memory-less and Causal/ Non-Causal Systems

Properties of Linear Systems

Example Problems-1

Example Problems-2

Example Problem-3

Properties and Analysis of LTI Systems-I

Properties and Analysis of LTI Systems-II

Properties and Analysis of LTI Systems-III

Properties of Discrete Time LTI Systems

Example Problems LTI Systems-I

Example Problems LTI Systems-II

Example Problems DT-LTI Systems

Laplace Transform

Laplace Transform Properties-I

Laplace Transform Properties-II

Laplace Transform of LTI Systems

Laplace Transform Example Problems-I

Laplace Transform Example Problems-II

Laplace Transform of RL, RC Circuit

Z-Transform

Z-Transform Properties-I

Z-Transform Properties-II

Z-Transform of LTI Systems

Z-Transform Examples-I

Z-Transform Examples-II

Z-Transform Examples-III

Z-Transform Examples-IV

Inverse Z-Transform

Fourier Analysis Introduction

Complex Exponential and Trigonometric FS

Conditions for Existence of FS

Fourier Transform (FT) Introduction

Properties of Fourier Transform-I

Properties of Fourier Transform-II

Fourier Transform – Parseval’s Relation

Fourier Transform of LTI Systems

FT- Ideal and Non-Ideal Filters

Fourier Analysis Examples-I

Fourier Analysis Examples-II

Fourier Analysis Examples-III

Fourier Analysis Examples-IV

Fourier Analysis Examples-V

Fourier Analysis Examples-VI

Fourier Analysis Bode Plot-I

Fourier Analysis Bode Plot-II

Fourier Transform Examples: Filtering – Ideal Low Pass Filter

Fourier Transform Problems: Unit Step Response of RC Circuit, Sampling of Continuous Signal

Sampling: Spectrum of Sampled Signal, Nyquist Criterion

Sampling: Reconstruction from Sampled Signal

Fourier Analysis of Discrete Time Signals and Systems – Introduction

Fourier Analysis of Discrete Time Signals – Duality, Parseval’s Theorem

Definition, Inverse DTFT, Convergence,DTFT and z-Transform, DTFT

DTFT Linearity, Time Shifting, Frequency Shifting, Conjugation, Time-Reversal, Duality

DTFT Differentiation in Frequency, Difference in Time, Convolution, Multiplication

DTFT: Discrete Time LTI Systems – LTI Systems Characterized by Difference Equations

Definition, Inverse DFT, Relation between DFT and DFS, Relation between DFT and DTFT, Properties

Conjugation, Frequency Shift, Duality, Circular Convolution, Multiplication, Parseval’s Relation

Example Problems: DFS Analysis of Discrete Time Signals, Problems on DTFT

Example Problems: DTFT of Cosine, Unit Step Signals

DTFT Example Problems-III

DTFT Example Problems-IV

DTFT Example Problems-V

DFT Example Problems-I

Example Problems: DFT, IDFT in Matrix form

Group/ Phase Delay – Part I

Group/ Phase Delay – Part II

IIR Filter Structures: DF–I, DF–II

IIR Filter Structures: Transpose Form

IIR Filter Structures: Example

IIR Filter Structures: Cascade Form

IIR Filter: Parallel Form – I & II

Description:

COURSE OUTLINE: This course introduces the fundamental principles of signals and system analysis. These concepts form the building blocks of modern digital signal processing, communication and control systems. Hence, a sound understanding of these principles is necessary for all students of Electronics and Communication Engineering (ECE), Electrical and Electronics Engineering (EEE), and Instrumentation Engineering (IE). This course is suitable for all UG/PG students and practicing engineers/ managers who are looking to build a solid grasp of the fundamental concepts of signals and systems as well as students/ professionals preparing for their college/ university/ competitive exams.

Principles of Signals and Systems

NPTEL

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#Engineering #Electrical Engineering #Signal Processing #Fourier Analysis #Z-Transform #Mathematics #Mathematical Analysis #Laplace Transform #Linear Time-Invariant Systems

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