113-1
工科所 Engineering Science
積體光子量子技術 Integrated Photonic Quantum Technologies
透過量子技術操控光或物質的量子疊加態與量子糾纏態,可以超越古典極限、達成傳統工程方式無法實現之任務。其中,積體量子光子學技術,透過積體化方法將光子源、光子操控元件、光子迴路、光子感測器集成於數毫米大小之晶片上,提高了量子任務之複雜性與一般性、促進了量子技術之實用性與商業價值;於本課程中將介紹積體光子量子技術之核心基本原理與實現方法,回顧與探討當前此領域之最新進展,並深入了解積體量子光子學技術之應用,包含量子計算、量子通訊與量子模擬。 Manipulating the quantum superposition state and quantum entangled state of light or matter through quantum technology can surpass the classical limit and achieve tasks that cannot be achieved by traditional engineering methods. Among them, the integrated quantum photonics technology integrates photon sources, photon control elements, photon circuits, and photon sensors on a chip with a size of several millimeters through an integrated method, which improves the complexity and generality of quantum tasks, and promotes The practicality and commercial value of quantum technology; in this course, we will introduce the core basic principles and implementation methods of integrated photonic quantum technology, review and discuss the latest developments in this field, and have an in-depth understanding of the application of integrated quantum photonics technology , Including quantum computing, quantum communication and quantum simulation.
理學院(模組化課程) Modular Course, College of Science
糾纏光子與光子量子計算 Entangled Photons and Photonic Quantum Computing
“糾纏光子”具備奇異的量子特性,作為“光子量子計算”重要之媒介與資源,與傳統資訊處理相較起來,這種嶄新的資訊處理方式具備更快之計算效率,並讓資訊保存與傳遞更加安全。本課程將介紹糾纏光子之製造、轉換與識別所需的基本概念與實現方法,了解如何利用光子的糾纏特性完成光子量子計算,與當前光子量子資訊處理之最新進展。 Entangled photons possess strange quantum characteristics, which serve as an important medium and resource for photonic quantum computation. Compared to the traditional information processing, such novel quantum technology provides superior efficiency and unconditional security for transmitting and storing information. Here, we will systematically introduce the concepts and methods of generation, transformation, and identification of entangled photons. We will also detail how the photon entanglement can be utilized to implement quantum computing. The advances of generic quantum photonic technology will be reviewed as well.
112-2
工科系 Engineering Science
近代物理 Modern Physics
本課程為物理學的延伸,提供工程領域的學生理解近代物理的發展內涵。課程介紹在電磁學、光學及狹義相對論之時空關係,其次介紹量子理論,最後再簡介量子物理的一些範例。 This course is an extension of physics, providing students in the engineering field to understand the development connotation of modern physics. The course introduces the space-time relationship of electromagnetics, optics, and special relativity, followed by quantum theory, and finally introduces some examples of quantum physics.
工科系 Engineering Science
量子光子學導論 Introduction to Quantum Photonics
量子光子學探討單光子量子狀態的製造、放射、傳遞、轉換、放大等基本原理,亦包含了相關工程化,如積體化,與同調控制光子系統之實務方法,其成為重要量子致能技術之關鍵,例如量子通訊、量子感測、量子模擬,與量子資訊處理等量子技術;於本課程中將介紹量子光子學核心基本概念,與其於相關量子技術應用上之實現方法。 Qantum technology applications. The content covers the following five Key points: 1. Importance of engineered single-photon systems; 2. Differences between classical engineering optics and quantum photonics; 3. Basic properties of photons; 4. Principles and methods of manufacturing, manipulation and detection of single photons and entangled photons ; 5. Integrated photon quantum technology.
112-1
工科所 Engineering Science
量子通訊 Quantum communications
本課程介紹量子通訊之基本概念與實現方法,內容涵蓋(1) 量子訊息傳遞媒介之量子特性;(2)古典與量子訊息辨別方式;(3) 量子通訊方案;(4) 量子通訊安全性分析;(5) 量子網路;(6) 量子通訊實現技術、現況與未來展望。 This course introduces the basic concepts and implementation methods of quantum communication, covering 1. Quantum characteristics of quantum message transmission media; 2. Distinguishing forms between classical and quantum messages; 3. Quantum communication solutions; 4. Quantum communication security analysis; 5. Quantum network; 6. Quantum communication implementation technology, current situation, and prospects.
理學院(模組化課程) Modular Course, College of Science
糾纏光子與光子量子計算 Entangled Photons and Photonic Quantum Computing
“糾纏光子”具備奇異的量子特性,作為“光子量子計算”重要之媒介與資源,與傳統資訊處理相較起來,這種嶄新的資訊處理方式具備更快之計算效率,並讓資訊保存與傳遞更加安全。本課程將介紹糾纏光子之製造、轉換與識別所需的基本概念與實現方法,了解如何利用光子的糾纏特性完成光子量子計算,與當前光子量子資訊處理之最新進展。 Entangled photons possess strange quantum characteristics, which serve as an important medium and resource for photonic quantum computation. Compared to the traditional information processing, such novel quantum technology provides superior efficiency and unconditional security for transmitting and storing information. Here, we will systematically introduce the concepts and methods of generation, transformation, and identification of entangled photons. We will also detail how the photon entanglement can be utilized to implement quantum computing. The advances of generic quantum photonic technology will be reviewed as well.
111-2
工科系 Engineering Science
近代物理 Modern Physics
本課程為物理學的延伸,提供工程領域的學生理解近代物理的發展內涵。課程介紹在電磁學、光學及狹義相對論之時空關係,其次介紹量子理論,最後再簡介量子物理的一些範例。 This course is an extension of physics, providing students in the engineering field to understand the development connotation of modern physics. The course introduces the space-time relationship of electromagnetics, optics, and special relativity, followed by quantum theory, and finally introduces some examples of quantum physics.
工科所 Engineering Science
量子光子學導論 Introduction to Quantum Photonics
量子光子學探討單光子量子狀態的製造、放射、傳遞、轉換、放大等基本原理,亦包含了相關工程化,如積體化,與同調控制光子系統之實務方法,其成為重要量子致能技術之關鍵,例如量子通訊、量子感測、量子模擬,與量子資訊處理等量子技術;於本課程中將介紹量子光子學核心基本概念,與其於相關量子技術應用上之實現方法。 Qantum technology applications. The content covers the following five Key points: 1. Importance of engineered single-photon systems; 2. Differences between classical engineering optics and quantum photonics; 3. Basic properties of photons; 4. Principles and methods of manufacturing, manipulation and detection of single photons and entangled photons ; 5. Integrated photon quantum technology.