工程硕士光学工程领域专业学位研究生培养方案.doc

工程硕士光学工程领域专业学位研究生培养方案 （代码：085202 授工程硕士专业学位） 一、培养目标 1．掌握本领域坚实的基础知识和系统的专门知识；掌握本领域的基本研究方法与技能，具备一定的研究实际问题的能力； 2．掌握并能熟练运用一门外国语； 3．培养严谨求实的学习态度和工作作风； 4．可胜任本领域的相关的工作。 二、主要研究方向 1．光通信系统及器件； 2．光电检测与信息处理技术； 3．激光技术与器件； 4．太赫兹光电子学； 5．微光机电技术； 6．光电显示、太阳能电池材料与器件。 三、学习年限与培养方式 培养方式为全日制，专业硕士学位的学习年限一般为2年。 四、学分要求与分配 总学分要求≥32学分，其中学位课学分要求≥18学分，研究环节要求≥14学分，具体学分分配如下表： 总学分 ≥32学分 修 课 学 分 ≥18学分 校级公共课程≥7学分，其中：英语2学分，思政类2学分、数学3学分 专业领域基础课≥2学分（必修） 专业选修课≥6 学分 实践教学（实验、设计、调查分析）≥3 学分 补修课程、任选课程只计成绩，不计学分 研 究 环 节 ≥14学分 专业课程实习实践（含报告） 4学分 实践环节 ≥4学分 专业实训（含报告） 4学分 开（选）题报告 1学分 必修 论文中期进展报告 1学分 必修 专业学位论文 8学分 必修 五、课程设置及学分分配 光学工程领域专业学位硕士研究生课程设置 类别 课程 课程 代码 课程名称 学时 学分 季节 开课单位 备注 学位课程 ≥18学分 公共 课程 ≥7 学分 411.500 第一外国语（英语） 32 2 秋 外语学院 必修 408.601 中国特色社会主义理论与实践研究 36 2 秋 马院 011.700 应用高等工程数学 48 3 秋 数学学院 408.602 自然辩证法概论（理工） 18 1 秋 马院 选修 专业领域基础课≥2 学分 182.535 光电技术概论 48 3 秋 光学与电子信息学院 必修 专业 选修课 限定 选修 ≥6 学分 182.501 光电信号处理 48 3 秋 光学与电子信息学院 182.503 现代实用光学系统 48 3 秋 光学与电子信息学院 182.502 光波导技术 32 2 秋 光学与电子信息学院 182.537 激光加工工艺 32 2 秋 光学与电子信息学院 182.513 光电信息与通信系统 32 2 秋 光学与电子信息学院 182.516 光电成像与遥感技术 32 2 春 光学与电子信息学院 182.518 半导体激光器及其应用 32 2 春 光学与电子信息学院 182.519 光电技术 32 2 春 光学与电子信息学院 182.528 空间激光通信原理与技术 32 2 春 光学与电子信息学院 182.508 光通信与光交换技术 32 2 秋 光学与电子信息学院 182.522 光电检测与光学图像信号处理 32 2 春 光学与电子信息学院 182.541 微纳光子器件数值仿真 32 2 春 光学与电子信息学院 182.542 宽带光接入网 32 2 秋 光学与电子信息学院 182.799 光纤传感技术 32 2 春 光学与电子信息学院 182.798 光纤通信原理与系统设计 32 2 春 光学与电子信息学院 182.797 参加学术讲座或学术报告 （合计至少6次） 1 光学与电子信息学院 实践教学（实验、设计、调查分析）≥3学分 182.538 光电技术综合实验 64 4 光学与电子信息学院 182.796 项目管理实践 2 光学与电子信息学院 182.795 光电领域调查分析报告 1 光学与电子信息学院 182.794 光电行业发展报告 1 光学与电子信息学院 非学位课 补修 课程 BX182.01 工程光学 40 秋 光学与电子信息学院 本科非光电类的硕士生必修 实践 研究 环节 ≥14学分 650.705 专业课程实习实践（含报告） 4 光学与电子信息学院 必修学分≥4学分 650.706 专业实训（含报告） 4 光学与电子信息学院 650.708 开（选）题报告 1 光学与电子信息学院 必修 650.709 论文中期进展报告（硕） 1 光学与电子信息学院 必修 650.710 专业学位论文（硕） 8 光学与电子信息学院 必修 六、实践环节 实践教学不少于半年；以就业目标为对象，凡直接服务于就业目标的学习、实习、研发等活动，均属于应用于实践活动，包括校内实验教学、参与导师课题的研发，校外企事业单位的实习实践等。 七、学位论文 论文必须以完成一个工程课题为选题原则，既可以是校外企业的课题，也可以是导师研究项目中的课题，要相对完整，具有可操作性，并兼顾一定的学术性。 八、学位授予 论文评阅和答辩必须有一名专业技术职务老师（副高级及以上）参加。课程考核合格、学分修满且论文答辩通过者，授予工程硕士专业学位。 Educational Plan for Master Degree Program Optical Engineering （Discipline code: 085202 Master of Engineering） I. Educational Objectives 1. Be able to master the basic theory, professional knowledge in the field of optical engineering; master basic research approach and skills in this field, develop the ability to solve practical problems; 2. Master a foreign language; 3. Be trained to have rigorous and realistic scientific attitude and good work ethic; 4. Be competent in the field of optical engineering and related field. II. Main Research Areas 1. Optical Communication Networks System and devices; 2. Optoeletronic detection & information process technology; 3. Laser technology and devices; 4. Terahertz Optoelectronics; 5. MOEMS technology; 6. Photoelectric display, solar cell materials and devices. III. The Length of Schooling and Training Mode The M.Eng Student should be studied in full-time scheme. The M.Eng Student are trained in terms of professional courses, professional practice and final thesis, which should be completed no longer than 2 years. IV. Credit Requirement and Allocation Each student is required to gain at least 32 credits, including at least 18 courses learning credits and 14 research credits, as show in the following table. Total Credits ≥32 credits Courses learning ≥18 credits Public courses credit ≥ 7 credits, including 2 for English course, 2 for political courses, 3 for mathematical courses. Fundamental requisite courses ≥ 2 credits Fundamental optional courses ≥ 6 credits Practices (experiments, design and survey analysis) ≥ 3 credits Only scores but no credits for redeemed and voluntary courses. Research ≥14 credits Special course design and reports 4 credits Practical phase ≥4 credits Special practices and reports 4 credits Thesis topic selection report 1 credit Required Thesis interim report 1 credit Required The final thesis 8 credits Required V. Curriculum Provision and Credit Allocation Curriculum for Master of Optical Engineering Courses type Course code Course name Time Credit Semester Department Other Degree requird courss Study ≥ 18 credits Public courses≥ 7 credits 411.500 First foreign language（English） 32 2 autumn Schoool of Foreign language Required 408.601 Theory and Practice of Scientific Socialism with Characteristics 36 2 autumn School of Marxism 011.700 Advanced Engineering Mathematics 48 3 autumn School of Mathematics and Statistics 408.602 Dialectics of Nature 18 1 autumn School of Marxism Elective Professi-onal fundam-ental course≥ 2 credits 182.535 Introduction for Optoelectronic Technology 48 3 autumn School of Optical and Electronic Information Required Professi-onal optional courses ≥ 6 credits 182.501 Optoeletronic signal processing 48 3 autumn School of Optical and Electronic Information 182.503 Modern practical optical system 48 3 autumn School of Optical and Electronic Information 182.502 Optical Waveguide Technology 32 2 autumn School of Optical and Electronic Information 182.537 Laser processing technics 32 2 autumn School of Optical and Electronic Information 182.513 Optoelectronic Information and Communication System 32 2 autumn School of Optical and Electronic Information 182.516 Imaging and remote sensing technology 32 2 spring School of Optical and Electronic Information 182.518 Semiconductor Lasers and Their Applications 32 2 spring School of Optical and Electronic Information 182.519 Optoelectronic Technology 32 2 spring School of Optical and Electronic Information 182.528 The Principle and Technology of Free Space Optical communication 32 2 spring School of Optical and Electronic Information 182.508 The Technology of Optical Communication and Photonics Switching 32 2 autumn School of Optical and Electronic Information 182.522 Photoelectricity detecting & image processing 32 2 spring School of Optical and Electronic Information 182.541 Simulations of Micro-Nano photonics devices 32 2 spring School of Optical and Electronic Information 182.542 Broadband optical access network 32 2 autumn School of Optical and Electronic Information 182.799 Optical fiber sensing technology 32 2 spring School of Optical and Electronic Information 182.798 Principle and system design for Optical fiber communication 32 2 spring School of Optical and Electronic Information 182.797 Attend academic lectures or academic report（≥6） 1 School of Optical and Electronic Information Practice Course （Expe-riments, design, survey）≥3 credits 182.538 Optoelectronic technology Experiment 64 4 School of Optical and Electronic Information 182.796 Practice of project management 2 School of Optical and Electronic Information 182.795 Survey analysis report in optoelectronic field 1 School of Optical and Electronic Information 182.794 Optoelectronic Industry development report 1 School of Optical and Electronic Information Non-degree required course Redeem-ed course BX 182.01 Engineering Optics 40 autumn School of Optical and Electronic Information required course for students not majored in optics Practical and Research Phase ≥14 credits 650.705 Professional courses practices and reports 4 School of Optical and Electronic Information required credit ≥4 credit 650.706 Professional field work and reports 4 School of Optical and Electronic Information 650.708 Thesis topic selection report 1 School of Optical and Electronic Information Required 650.709 Thesis interim report 1 School of Optical and Electronic Information Required 650.710 The final thesis 8 School of Optical and Electronic Information Required VI. Internship and Practical Training Students are required to take professional practices no less than 6 months; professional practice includes Professional courses, field work, research work, which benefits students’ future career, such as taking experimental course on campus, participating in tutor’s research project, internship in companies and institutions outside campus, and etc. VII. Degree Thesis Thesis topic should be about the entire process of finishing an engineering project. This project could be a project in companies or institutions off campus, or tutor’s research project. The project should be practical, relatively complete, and includes technicality to a certain degree. VIII. Degree Awarding At least one professional teacher, who has associate professorship or above, should evaluate the thesis and attend final thesis defense. When graduate student has passed course exams, gained enough credits, finished research work and final thesis, and passed thesis presentation and check of HUST Degree Award Committee, he will be awarded the Master’s degree in Engineering.