UNIT – I

Introduction to signals and systems
Signals: Definition – Classification of signals : Continuous time – Discrete time – Deterministic & Random – Periodic & Non-periodic – Even & odd – Energy & Power signals – Basic operations on Independent Variable: Time Shifting -Time scaling – Time Reflection – Basic operations on Dependent Variable: Amplitude scaling, Addition, Multiplication, Differentiation and Integration – Basic elementary signals: Complex exponentials & sinusoidal – unit impulse – unit step – unit ramp.
Systems: Definition – Classification of systems: Continuous time – Discrete time systems – Basic system properties: Linearity – Time invariance – Memory and Memory less – Causality – Invertibility and Inverse – Stability.

UNIT – II

Linear Time Invariant Systems
Representation of discrete & continuous time signals in terms of impulses – Convolution sum – Convolution integral – Properties of convolution: Commutative, Associative and Distributive – Properties of LTI systems: Memory and Memory less – Invertibility – Causality – Stability – Unit step response of an LTI systems – Casual LTI systems described by Differential & Difference equations.
Sampling: Sampling theorem, Definition of CTFT and inverse CTFT, Definition of DTFT and inverse DTFT, Definition of Z transform- Region of convergence – Inverse Z transform (Partial fraction method)

UNIT – III

Basic Concepts of Control System
Introduction: Definition of system, control system – Classification of system- open loop and closed loop systems – Mathematical models: Transfer function model, State model.
Transfer function model: Block diagram representation – Reduction of Block Diagram – Techniques – Signal flow graph representation – Mason’s formula – Block diagram to Signal flow graph – Examples and problems – Derivation of transfer function of dc motor.
State Model: Definition of state space & State variables – Modeling of dynamic systems using state variables – Examples.

UNIT – IV

Time and Frequency Response of Linear Systems
Type and order of a system -First order and second order systems – Systems with unity and non – Unity feedback – Impulse response and step response of first and second order linear systems.
Time domain specifications: rise time, delay time, overshoot and settling time of first order and second order systems.
Steady state error and error constants – Generalized error constants – Problems.
Frequency Response
Frequency response specifications: resonant peak, resonant frequency, bandwidth, cut-off rate -correlation between time and frequency response of second order system.

Course Objectives:

• to represent any arbitrary signals in time and frequency domains and design LTI systems with specific impulse / step responses
• Introduce the basic concepts of control system, its types, transfer function and state space models
• To analyse the linear time invariant system in time and frequency domains and also to find the system specification in both the domains

Course Outcomes:
After completing this course, students should be able to

• Design and test CT / DT LTI systems in both the time and frequency domains
• Apply unit impulse function and basic complex exponentials for system analysis
• Design a control system for a linear time invariant, single input and single output system
• Evaluate the time and frequency responses of the systems

Online Materials

NPTEL – http://www.youtube.com/playlist?list=PL75A2863DF4CE1CE6
NPTEL – http://nptel.ac.in/courses/108102043/

CO-PO Mapping

1. Tarun Kumar Rawat,Signals and Systems, Oxford University Press, Fifth Reprint, 2012.
2. Alan V. Oppenheim and Alan S. Willsky with S. Hamid Nawab, Signals and Systems, Pearson Education, 2nd Edition, 2008.
3. I.J. Nagrath & M. Gopal, Control System Engineering, New Age International, 2001.
4. Katsuhiko Ogata, Modern Control Engineering, 3rd Edition, Prentice Hall, India, New Delhi, 2000.
5. S.K.Bhattacharya, Linear Control System, 2ndEdition, Pearson education, 2011.