FI:IA082 Quantum information processing - Course Information

IA082 Physical concepts of quantum information processing

Extent and Intensity

2/0/0. 2 credit(s) (plus extra credits for completion). Recommended Type of Completion: zk (examination). Other types of completion: k (colloquium).

Teacher(s)

RNDr. Daniel Reitzner, PhD. (lecturer)
doc. Mgr. Mário Ziman, Ph.D. (lecturer)

Guaranteed by

doc. Mgr. Mário Ziman, Ph.D.
Department of Computer Systems and Communications – Faculty of Informatics
Supplier department: Department of Computer Systems and Communications – Faculty of Informatics

Timetable

Thu 16. 2. to Thu 11. 5. Thu 18:00–19:50 B411

Prerequisites (in Czech)

PV275 Intro to Quantum Programming || SOUHLAS

Course Enrolment Limitations

The course is also offered to the students of the fields other than those the course is directly associated with.

fields of study / plans the course is directly associated with

there are 54 fields of study the course is directly associated with, display

Course objectives

Introduction to quantum physics and quantum information theory.

Learning outcomes

After this course students should:
understand basic principles of quantum physics;
apply the learned concepts in the subsequent study of quantum information theory;
self-study quantum theory books.

Syllabus

• 1. Security and computation with photons - photon's polarization and polarizers, Vernam cipher, quantum key "distribution" protocol B92, polarizing beam-splitter, √NOT logic gate,
• 2. Quantum interference and superposition - Mach-Zender interferometer, concept of quantum state, quantum probabilities and amplitudes, Hilbert space and operators,
• 3. Measuring quantum properties - description of quantum measurement devices (POVM), tomography of polarization, uncertainty relations, no information without disturbance
• 4. Hydrogen atom - emission spectrum, Bohr's model, position and momentum, quantum solution, Zeeman effects, spin of electron,
• 5. Schrodinger equation - time and evolution, unitary operators, energy conservation and system's Hamiltonian,
• 6. Quantum bit - two-level quantum system (polarization and spin-1/2), Stern-Gerlach experiments, Bloch sphere, orthogonality and information, no-cloning theorem, quantum NOT gate, qubit implementations
• 7. Quantum sources and randomness - mixed states, quantum commpression, von Neumann entropy, capacity of noiseless quantum channel, randomness sources, min-entropy
• 8. Einstein-Podolski-Rosen paradox - composite quantum systems, tensor product, quantum steering, EPR paradox, local hidden variable model, CHSH inequalities, experiments and loopholes
• 9. Quantum one-time pad protocols - one-time pad, super-dense coding and teleportation
• 10. Quantum entanglement - correlated and separable states, definition of entanglement, entanglement distilation,
• 11. Quantum cryptography - QKD protocols BB84, E91, no-quantum bit commitment theorem, quantum secret sharing protocols,
• 12. Elementary particles - fermions and bosons and tensor products, standard model, Higg's boson

Literature

• ZIMAN, Mário. Vybrané kapitoly z kvantové mechaniky (Selected topics from quantum mechanics). 2004. URL info

Teaching methods

Lectures

Assessment methods

Homeworks and written exam, usage of materials and notes is allowed, optional oral exam

Language of instruction

Czech

Further Comments

Study Materials
The course is taught annually.

Teacher's information

http://quantum.physics.sk/rcqi/index.php?x=fimu_qm

• Enrolment Statistics (Spring 2023, recent)
  
• Permalink: https://is.muni.cz/course/fi/spring2023/IA082