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The document outlines a Master of Technology program in Quantum Computing, highlighting its potential to revolutionize industries and the need for skilled professionals in this field. It details the prerequisites for students and the skills they will acquire upon completion, including access to quantum computing services and the ability to design quantum circuits. Additionally, it includes a course syllabus for Linear, Nonlinear, and Quantum Optics, covering various topics in optics and their applications.

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27 views2 pages

Syl 1

The document outlines a Master of Technology program in Quantum Computing, highlighting its potential to revolutionize industries and the need for skilled professionals in this field. It details the prerequisites for students and the skills they will acquire upon completion, including access to quantum computing services and the ability to design quantum circuits. Additionally, it includes a course syllabus for Linear, Nonlinear, and Quantum Optics, covering various topics in optics and their applications.

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srigurulearn
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© © All Rights Reserved
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Annexure - 3a

M.T ECH . (Q UANTUM C OMPUTING )


Approved by All India Council for Technical Education, New Delhi,
Commissioner of Technical Education, Madhya Pradesh and
Rajiv Gandhi Technological University, Bhopal.

Affiliated to
Rajiv Gandhi Technological University, Bhopal.

A BOUT THE P ROGRAM


Like the first digital computers, quantum computers offer the possi-
bility of technology exponentially more powerful than current sys-
tems. They stand to change companies, entire industries, and the
world by solving problems that seem impossible today.
A recent report states that by 2023, 20% of organizations will be
budgeting for quantum computing projects. As this new technol-
ogy develops, organizations will face a shortage of quantum com-
puting experts.
The time to learn about quantum computing is now. Discover the
technical implications of this new frontier in computing and how
you can apply quantum computing to every problem in engineering
and technology.

S TAKE H OLDERS
Any one interested in this area are welcomed to learn the courses.
However, we prefer students with basic knowledge of program-
ing skills, elementary Physics, knowledge of matrix operations and
transforms and skills in logical operations.
We are

A FTER S UCCESSFUL C OMPLETION ,


You will be:
• able to access the quantum computing services provided by
IBM, Amazon Brakt, D-Wave QPU, IonQ, Rigetti and other
quantum computing services Simulators.

• able to think independently of quantum circuits, algorithm


and applications for real-time stochastic problems in QC.
• trained to design QC ciruits and reversible logics for real-
world problems.
Annexure - 3b

PH66010 : L INEAR , N ONLINEAR AND Q UANTUM O PTICS


(Credits: L-3,P-0,T-0. Marks: CW+TH=30+70)
Course Objectives
CO#1. Develop a familiarity with the ray optics and gaussian beam.
CO#2. Cultivate the fundamental understanding of electromagnetism.
CO#3. Deliver the knowledge about Fourier and nonlinear optics.
CO#4. Develop elementary problem-solving capability of quantum optics
Course Outcome
CO#1. Have deep understanding of EM wave propagation in guided medium.
CO#2. Demonstrate various fabrication and cabling techniques of optical fiber and its
application.
CO#3. Solve the problems attributed spatial frequency filtering and quantum optics.
CO#4. Deliver the knowledge about the various optical nonlinear phenomena.
Syllabus
Unit 1. Linear Optics: Postulates of ray optics, planar and spherical boundaries, Graded
index optics and materials, ray transfer matrix, ABCD Matrix method for optical
components, Interference of waves, Gaussian beam and its propagation through op-
tical elements.
Unit 2. Electromagnetism: Refraction, Absorption and dispersion of electromagnetic waves,
polarization and crystal optics, Propagation of electromagnetic waves through anisotropic
media.
Unit 3. Fourier Optics: Correspondence between spatial harmonic functions and plane waves,
transfer function and impulse response function of free space, Fourier transform in the
far field, propagation of light in free space, Fourier transform using a lens, diffraction
of light, image formation, spatial frequency filtering.
Unit 4. Nonlinear Optics: Nonlinear optical susceptibility, second-order optical susceptibil-
ities, phase matching, sum, frequency and second-harmonic generation. Third-order
optical susceptibility, two photon absorption, nonlinear refraction and absorption,
four-wave mixing, optical bistability.
Unit 5. Quantum Optics: Quantization of single mode field, quantization of multimode
fields, eigenstates, annihilation and creation operators, wave packets and time evolu-
tion, general idea of sqeezed states.

Text Books
1. B. E. A. Saleh and M. C. Teich, Fundamentals of Photonics, Second Edition, John Wiley & Sons-NY, 2007.
2. C. Gerry and P. L. Knight, Introductory Quantum Optics, Camridge Unv. Press, 2005.
3. K. Iizuka, Elements of Photonis Vol I & II, Wiley, New York, 2003.

Reference Books
1. A. Yariv and P. Yeh, Optical Waves in Crystal, Wiley, New York, 1983.
2. A. Ghatak and K. Thyagarajan, Optical Electronics, Cambridge Univ. Cambridge, 1989.
3. A. Yariv, Quantum Electronics, 2nd Edition, Wiley, New York, 1975.

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