Page 238 - handbook 20162017
P. 238
Faculty of Science Handbook, Session 2016/2017
SIF2021 DIGITAL ELECTRONICS (3 CREDITS) SIF2022 MATHEMATICAL METHODS II (3 CREDITS)
Digital number system: binary, octal, hexadecimal, binary coded Fourier Series and Transformation Series: Periodic functions, Fourier
decimal series, average value of a function, Fourier coefficient, Dirichlet
Logic gates: AND, OR NAND, NOR, XOR, XNOR; logic gates TTL condition, complex form of Fourier Series, general interval, even and
Logic circuits: Boolean algebra, truth table for Boolean expression, odd functions, Parseval theorem. Fourier transformation, and Parserval
derivation circuit from Boolean expression Theorem.
Karnaugh map simplification with three, four and five variables Coordinate Transformation: Linear transformation, orthogonal
TTL chip specification, CMOS, interface, transformation, eigen value and eigen vector and diagonalization of
Schmitt Trigger: Function and functional matrices. Curvilinear coordinates, scalar factor and fundamental vector
Combinational logic circuit: half adders, full adder, binary multiplication for orthogonal system, general curvilinear coordinates, vector operator
Sequential logic: SR, JK, D, T flip flops in orthogonal curvilinear coordinates.
Register: parallel, series, shifter, ring counter, frequency divider Special Functions: Factorial functions, Gamma functions, Beta
Memory: RAM, ROM, PROM etc functions, relationship between Beta and Gamma functions, error
Digital device, PLD, PAL, PLC, micro-controller functions, asymptotic series, Stirling formula and elliptical functions.
Analog digital interface Series Solution for Differential Equations: Legendre equations, Leibnitz
rule, Rodriguez formula, generating functions for Legendre polynomial,
Assessment Method: orthogonal functions, orthogonalization and normalization of Legendre
Final Examination: 60% polynomials, Legendre series, Associate Legendre function, Frobenius
Continuous Assessment: 40% method, Bessel equation, second solution of Bessel equation,
recurrence relationship, general differential equation with Bessel
Medium of Instruction: function as a solution, orthogonalization of Bessel function, Hermite
English function, Laguerre function, step operator.
Partial Differential Equation: Laplace equation, steady state
Soft-skills: temperature in a square plate, Schrödinger equation, heat and diffusion
CS2, CTPS3, LL2, EM1 equation. Wave equation, vibrating string, steady state temperature in
a cylinder, steady state temperature in a sphere, Poisson equation.
References:
1. Thomas L. Floyd, Digital Fundamentals, 11 edition (Pearson, Assessment Method:
2014) Final Examination: 60%
2. R.L. Tokheim, Digital Electronics: Principles and applications, 8th Continuous Assessment: 40%
ed. (Glencoe McGraw-Hill, 2013)
3. Anant Agarwal, Jeffrey Lang, Foundations of Analog and Digital Medium of Instruction:
Electronic Circuits (Morgan Kaufmann, 2015) English
4. Roger Tokheim, Digital Electronics: Principles and Applications
(McGraw-Hill, 2013) Soft-skills:
CTPS3
SIF3010 MICROPROCESSOR (3 CREDITS)
Calculation using various number systems- binary, octal, hexadecimal, References:
binary coded decimal, calculation using the ASCII code. Introduction to 1. K. F. Riley, M. P. Hobson, Essential Mathematical Methods for the
microprocessors: Basic definitions, word length, concept of addresses, Physical Sciences (Cambridge University Press, 2011)
data bus, address bus, and control bus, programming, microprocessor 2. G.B. Arfken, H.J. Weber, Mathematical Methods for Physicists: A
systems and microcontrollers. Microprocessor architecture: internal Comprehensive Guide, 7th Edition (Elsevier Acad. Press, 2012)
organization, programming models, the arithmetic and logic unit, 3. G. N. Felder, K. M. Felder, Mathematical Methods in Engineering
registers, stack pointer, internal data bus and logic controller. Memory: and Physics (John Wiley & Sons, 2015)
types of memory, memory chips, connections to the microprocessor,
interfacing and expansion technique, using technique and secondary SIF3011 QUANTUM MECHANICS II (3 CREDITS)
storage. Communicating with the outside world, input and output (I/O), General formalism of quantum mechanics. Time-independent
connectivity and the timing diagram, programming the I/O chip, serial perturbation theory. Time-dependent perturbation theory. Scattering
and parallel connection techniques, analogue to digital and digital to theory. Angular momentum. Additional of angular momentum.
analogue converters. Programming: algorithm and flowcharts, Relativistic quantum mechanics.
commands and its types, operation codes, addressing modes, flow of
information, assembly language, loops and subroutines. Interfacing: Assessment Method:
serial and parallel techniques, functions and characteristics of UART, Final Examination: 60%
baud rate and it effects, serial data control word, interfacing standards, Continuous Assessment: 40%
handshaking principles
Medium of Instruction:
Assessment Method: English
Final Examination: 60%
Continuous Assessment: 40% Soft-skills:
CS3, CTPS3, LL2
Medium of Instruction:
English References:
1. James Binney, David Skinner, The Physics of Quantum
Soft-skills: Mechanics (Oxford University Press, 2014)
CS2, CTPS3, LL2 2. Kurt Gottfried, Tung-Mow Yan, Quantum Mechanics:
Fundamentals 2nd ed. (Springer, 2013)
References: 3. Reinhold Blumel, Advanced Quantum Mechanics: The Classical-
1. Jon Stokes, Inside the Machine: An Illustrated Introduction to Quantum Connection (Jones and Barlett, 2011)
Microprocessors and Computer Architecture (William Pollock, 4. David J. Griffiths, Introduction to Quantum Mechanics, 2nd ed.
2015) (Pearson Prentice Hall, 2004)
2. Subir Kumar Sarkar and Asish Kumar De,Foundation of Digital
Electronics and Logic Design (CRC Press, 2014) SIF3012 COMPUTATIONAL PHYSICS (3 CREDITS)
3. M. Rafiquzzaman, Fundamentals of Digital Logic and Ordinary Differential Equations: boundary-value and eigenvalue
Microcontrollers (Wiley, 2014) problems, Sturm-Liouville problem.
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