[{"data":1,"prerenderedAt":29},["ShallowReactive",2],{"program-msc-electromagnetics-fusion-space-105799":3},{"id":4,"name":5,"program":6,"department":7,"degree":8,"code":9,"gpa":10,"materials":10,"gre":10,"gmat":10,"ielts":10,"toefl":10,"studyMode":11,"years":8,"unit":12,"tuition":10,"startDate":13,"deadlineDate":14,"description":15,"add01Html":10,"universityId":16,"subjectAreaCode":8,"subjectAreaName":17,"subjectCode":18,"subjectName":19,"qsRank":20,"usNewsRank":20,"timesRank":20,"shanghaiRank":20,"dstatus":11,"createdTime":21,"updatedTime":22,"universityName":23,"unEnglishName":24,"unAbbreviation":25,"unQsRank":26,"unCode":27,"unCity":10,"universityCode":10,"countryCode":28},105799,"电磁学、聚变与空间工程硕士","MSc Electromagnetics, Fusion and Space Engineering","School of Electrical Engineering and Computer Science and Engineering Sciences","2","msc-electromagnetics-fusion-space-105799",null,1,"CNY","2025-10-16 00:00:00","2026-01-15 00:00:00","电磁学、聚变与空间工程硕士项目将扎实的电气工程基础与电磁场知识、电磁场如何与物质相互作用以及如何将其应用于技术相结合。学生可以专攻微波工程、光子学、等离子体或空间领域。由于该项目涵盖了该领域的理论和应用方面，毕业生在工业界和学术界都面临着多样化的职业机会。电磁场是电信的基础。例如，它们被用于通过光纤或移动无线系统传输高速数据。此外，电磁场从宇宙中的物体（如恒星）传输，提供重要信息以帮助我们了解宇宙。此外，控制和产生聚变能需要对电动力学和等离子体物理学有基本了解，聚变能有望在不久的将来为地球提供动力。鉴于这些目标，该项目围绕四个不同的重点领域构建：微波工程、光子学、等离子体、空间。学年分为四个学习阶段，每个阶段通常有2-3门课程。前两个阶段包括所有学生的共同必修课程。在随后的四个阶段，学生在其选择的专业内学习必修课和选修课。最后一个学期专门用于硕士学位项目，该项目可以与本地或国际行业合作进行。这是一个为期两年的英语授课项目（120学分），在一个国际化的环境中，有来自许多国家的学生。",2724,"工程与技术","204","电气与电子工程",0,"2025-10-25 13:01:37","2026-02-05 13:45:15","瑞典皇家理工学院","KTH Royal Institute of Technology","KTH","0","kth","se",1772699305624]