3. 강의목표
In this lecture we aim to introduce basic concepts of quantum information science. The idea of quantum bit (qubit) and decoherence will be discussed using a description of density matrices. We study the basic building blocks of quantum circuits, the single- and two-qubit quantum gates. Quantum Fourier transform and period finding are discussed to understand the renowned quantum protocols like Shor algorithm and Grover search. We further focus on quantum error correction, quantum communication, and quantum networks. On the experimental side we highlight the recent quantum technologies in various platforms, including trapped ions and superconducting qubits.
4. 강의선수/수강필수사항
general physics, linear algebra, basic quantum mechanics
5. 성적평가
midterm exam 40%, final exam 40%, homework 20%
6. 강의교재
| 도서명 |
저자명 |
출판사 |
출판년도 |
ISBN |
|
Quantum Computation and Quantum Information
|
Nielsen and Chuang
|
Cambridge
|
0000
|
|
|
Quantum Optics
|
Scully and Zubairy
|
Cambridge
|
0000
|
|
8. 강의진도계획
This is a tentative lecture plan.
- Status of quantum information science
- Review of linear algebra and basic quantum mechanics
- Quantum measurement, POVM
- Single and two-qubit quantum gates
- Entanglement, quantum teleportation
- Midterm exam
- Quantum Fourier transform and period finding
- Shor algorithm and Grover search
- Quantum error correction
- Quantum communication, QKD: BB84 protocol
- Quantum networks
- Recent quantum technologies: ion trap and circuit QED
- Final exam
11. 장애학생에 대한 학습지원 사항
- 수강 관련: 문자 통역(청각), 교과목 보조(발달), 노트필기(전 유형) 등
- 시험 관련: 시험시간 연장(필요시 전 유형), 시험지 확대 복사(시각) 등
- 기타 추가 요청사항 발생 시 장애학생지원센터(279-2434)로 요청