Budapest University of Technology and Economics, Faculty of Electrical Engineering and Informatics

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    Quantum Informatics Laboratory 

    A tantárgy neve magyarul / Name of the subject in Hungarian: Kvantuminformatika laboratórium

    Last updated: 2024. február 26.

    Budapest University of Technology and Economics
    Faculty of Electrical Engineering and Informatics

    Computer Engineering

    MSc  

    Specialization 
    Course ID Semester Assessment Credit Tantárgyfélév
    VIHIMB10   0/0/3/f 4  
    3. Course coordinator and department Dr. Gerhátné Udvary Eszter,
    4. Instructors
    Dr. László Bacsárdi, associate professor, HIT
    Dr.  Eszter Gerhátné Udvary, associate professor, HIT
    Dr. Sándor Imre, professor, HIT
    Dr. Ágoston Schranz, assistant professor, HIT 
    5. Required knowledge Quantum informatics, Quantum communication
    6. Pre-requisites
    Ajánlott:

    VIHIMA24           Quantum Computers and their Applications

    VIHIMA25           Quantum Communication Networks

    7. Objectives, learning outcomes and obtained knowledge The primary purpose of the laboratory is to illustrate and deepen the knowledge imparted in the two subjects of the Quantum Informatics secondary specialization through the students' personal experience. It covers testing modern quantum programming paradigms and BME's self-developed quantum network systems. Given that the EU will start building the pan-European quantum network in 2023 and that the Budapest University of Technology and Economics is a key domestic player in this process, we would like to provide an opportunity to learn about the network and gain practical experience.
    8. Synopsis
    Three hours of lab per week
         Introduction. Lab Use Policy Review.

     
         Operations on the Bloch sphere
         Measuring the properties of the optical fiber.
         Photon counter application
         Quantum-based random number generation
         Programming quantum computers based on circuit design
         Programming quantum computers with an instruction set
         Quantum Computing Development Environments: Q#
         Entanglement
         Free space quantum key distribution (time stamp, reference signal)

     
         Substitution of laboratory practice
    9. Method of instruction Laboratory: during the semester, knowledge of quantum computing and quantum communication is acquired through the completion of laboratory exercises
    10. Assessment
    During the semester, 9 laboratory measurements will be performed. Measurement guides are available for each, which should be reviewed before measurement. At the beginning of the measurement, an entrance test may be required. The measurement cannot be performed in the event of an unsuccessful entrance test. A report must be prepared during the lab.
    At least 8 laboratory measurements must be successfully completed.
    The grade of the subject is the average of the grades given for the 8 best lab reports.

    11. Recaps During the last week of the study period, we provide the opportunity to substitute a lab.
    12. Consultations Consultation is possible by appointment.
    13. References, textbooks and resources

    S. Imre, L. Gyöngyösi: Advanced Quantum Communications - An Engineering Approach, Publisher: Wiley-IEEE Press (New Jersey, USA), John Wiley & Sons, Inc., 2012 

     Additional materials  are available in electronic form.

    14. Required learning hours and assignment
    Kontakt óra42
    Félévközi készülés órákra78
    Felkészülés zárthelyire
    Házi feladat elkészítése
    Kijelölt írásos tananyag elsajátítása
    Vizsgafelkészülés
    Összesen120