#1
22nd June 2015, 03:30 PM
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SGBAU Syllabus BE IT
I want to do Bachelor of Engineering (BE) Information Technology IT from Gadge Baba Amravati University so provide me the syllabus, course structure and the curriculum of this course? Also tell me the intake capacity of BE Information Technology?
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#2
13th January 2020, 09:37 PM
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Re: SGBAU Syllabus BE IT
Can you provide me the syllabus for 4th year of the Bachelor of Engineering in Information Technology Program offered by SGBAU (Sant Gadge Baba Amravati University)?
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#3
13th January 2020, 09:39 PM
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Re: SGBAU Syllabus BE IT
The syllabus for 4th year of the Bachelor of Engineering in Information Technology Program offered by SGBAU (Sant Gadge Baba Amravati University) is as follows: SEMESTER: SEVENTH 7IT 01 DIGITAL SIGNAL PROCESSING Unit I: Discrete –Time Signals and Systems: Introduction to DSP, Advantages, basic elements of DSP system, sampling theorem, A/D, D/A conversion, quantization. Elementary discrete-time sequences. Discretetime systems: description, representation, classification (linear, time-invariant, static, casual, stable) Unit II: Analysis of DTLTI systems: The convolution sum, properties of convolution, Analysis of causal LTI systems, stability of LTI systems, step response of LTI systems, difference equation, recursive & non recursive discrete-time systems, solution of difference equations, Impulse response of LTI recursive system. Correlation of discrete time signals. Unit III: z- Transform and Analysis of LTI Systems: Definition of zTransform, properties, rational z-Transforms, evaluation of the inverse z- Transforms, analysis of linear time invariant systems in z-domain, transient and steadystate responses, causality, stability, pole-zero cancellation, the Schur-Cohn stability test Unit IV: Fourier Transforms, the DFT and FFT: Definition & properties of Fourier transform, relation with ztransform. Finite duration sequences and the discrete Fourier transform(DFT), properties, circular convolution, Fast algorithms for the computation of DFT: radix-2 and radix-4 FFT algorithms Unit V: Design of Digital Filters: Classification of filters: LP, HP, BP, FIR and IIR filters, filter specifications. Design of FIR filters using Windows and by Frequency sampling methods. Design of IIR filters from Analog filters using approximation of derivatives, Impulse invariant transformation, Bilinear transformation and Matched z-Transformation, Commonly used Analog filters and IIR Filter design example Unit VI: Realization of Discrete-Time systems: Structures for realization of Discrete-Time systems, realization of FIR systems: Direct Form, Cascade Form, Frequency sampling and Lattice structures. Realization of IIR filters: Direct Form, Signal flow graph and Transposed structures, Cascade form, Lattice and Lattice-ladder. Realization for IIR systems. TEXT BOOK : J G Prokis and D G Manolokis, “Digital Signal Processing: Principles Algorithms and Applications (Pearson Education) REFERENCE BOOKS: 1. S.Salivahanan, A Vallavaraj, C Gnanapriya “Digital Signal Processing” (TaTa McGraw Hill) 1. S K Mitra: “Digital Signal Processing: A Computer-Based Approach” (TaTa McGraw Hill) 2. E C Ifeacthor and B W Jervis “Digital Signal Processing A Practical Approach” (Pearson Education) 3. A V Oppenheim, R W Schafer with J R Buck “Discrete Time Signal Processing” (PHI) Syllabus 4th year BE Information Technology Sant Gadge Baba Amravati University |