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402-0448-01L 5 Credits DR , MSC D-ITET , D-MATH , D-INFK , D-MAVT , D-PHYS

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Quantum Information Processing I: Concepts

Lecturers & Examiners: Dr. Philipp Kammerlander

This theory part QIP I together with the experimental part 402-0448-02L QIP II (both offered in the Spring Semester) combine to the core course in experimental physics "Quantum Information Processing" (totally 10 ECTS credits). This applies to the Master's degree programme in Physics.

VVZ CR 3.6

Last Updated: 2026-02-05 15:41:55

Abstract

The course will cover the key concepts and ideas of quantum information processing, including descriptions of quantum algorithms which give the quantum computer the power to compute problems outside the reach of any classical supercomputer.Key concepts such as quantum error correction will be described. These ideas provide fundamental insights into the nature of quantum states and measurement.

Objective

We aim to provide an overview of the central concepts in Quantum Information Processing, including insights into the advantages to be gained from using quantum mechanics and the range of techniques based on quantum error correction which enable the elimination of noise.

Content

The topics covered in the course will include quantum circuits, gate decomposition and universal sets of gates, efficiency of quantum circuits, quantum algorithms (Shor, Grover, Deutsch-Josza,..), error correction, fault-tolerant design, entanglement, teleportation and dense conding, teleportation of gates, and cryptography.

Resources

Lecture Notes

More details to follow.

Literature

Quantum Computation and Quantum Information Michael Nielsen and Isaac Chuang Cambridge University Press

Learning Materials (Links)

Moodle course
Moodle-Kurs / Moodle course

General Information

Language: English
Levels: DR , MSC
Frequency: Yearly recurring

Examination

Type: session examination
Mode: oral 20 minutes

Course Components

Type	Title	Time & Place	Hours
lecture	Quantum Information Processing I: Concepts	Mon 13:45-15:30 (HPV G 5) Mon 14:00-16:00 (ER SA TZ)	2 h weekly
exercise	Quantum Information Processing I: Concepts	Mon 15:45-16:30 (HCI H 8.1) Mon 15:45-16:30 (HCI J 4) Mon 15:45-16:30 (HIL E 10.1) Mon 15:45-16:30 (HPV G 5) Mon 16:00-17:00 (ER SA TZ)	1 h weekly

Offered In

Computational Science and Engineering Master
- Fields of Specialization
  - Physics (For the field of specialization `Physics' basic knowledge in quantum mechanics is required.)
Micro- and Nanosystems Master
- Core Courses
  - Elective Core Courses
Physics Master
- Core Courses (One Core Course in Experimental or Theoretical Physics from Physics Bachelor is eligible; however, this Core Course from Physics Bachelor cannot be used to compensate for the mandatory Core Course in Experimental or Theoretical Physics. For the category assignment keep the choice "no category" and take contact with the Study Administration ( ) after having received the credits.)
  - Core Courses: Experimental Physics
Doctoral Dep. of Information Technology and Electrical Engineering (More Information at: )
- Doctoral and Post-Doctoral Courses (A minimum of 12 ECTS credit points must be obtained during doctoral studies. The courses on offer below are but a small selection out of a much larger available number of courses. Please discuss your course selection with your PhD supervisor.)
Data Science Master
- Core Courses
  - Core Electives
Quantum Engineering Master
- Core Courses (A minimum of 24 credits must be obtained from core courses during the MSc QE, course selection is subject to the tutor's agreement.)
  - Physics Core Courses (These core courses target students with an engineering background and all those who need additional physics foundations.)