{"title":"锡拉丘兹大学EMC教育中心","authors":"D. Weiner","doi":"10.1109/ISEMC.1992.626070","DOIUrl":null,"url":null,"abstract":"ELECTROMAGNETIC COMPATIBILITY is proposed as a new 500-level course in Electrical Engineering. This course will augment the relatively few design courses available to students in Electrical and Computer Engineering. It will also satisfy the need by industry for students who understand problems associated with designing electromagnetically compatible products. To enhance the design aspect of the course, demonstrations and experiments will be included. A) PROBLEM STATEMENT The accreditation board for Electrical and Computer Engineering undergraduate programs requires that undergraduate students take a minimum of 16 design credits. Currently, Electrical and Computer Engineering students at Syracuse University have little flexibility in selection of their design courses. To alleviate this situation, it is proposed to develop a new 500-level design course to be taught for senior and first-year graduate students. In selecting the topic area for such a course, consideration was given to industrial requirements. Manufacturers of electrical products and electronic systems are keenly aware of the importance of electromagnetic compatibility (EMC). For example, it is important that the electromagnetic radiation from a home computer not interfere with television reception. As a rule, industry cannot afford an in house program to train their beginning engineers to the necessary level of EMC design competence. Consequently, industry today considers a basic knowledge of EMC to be as important a part of an Electrical or Computer Engineer’s education as is circuits, digital design, signal theory, electromagnetics, etc. Nevertheless, according to a survey in 1985 by the Education Committee of the IEEE Electromagnetic Compatibility Society, only a few colleges and universities offer courses dealing with EMC. In spite of this, most respondents felt that there was a need to include this material in the Electrical Engineering curriculum. To satisfy this need, ELECTROMAGNETIC COMPATIBILITY was selected as the subject matter for the new design course. B) OBJECTIVES The course material will be based on the text, INTRODUCTION TO ELECTROMAGNETIC COMPATIBILITY, by C.R. Paul. The manuscript has only recently been accepted for publication by John Wiley and Sons, Inc. (I served as one of the reviewers for John Wiley.) A course outline, based on this text, is included with the supporting documents. In a design course of this nature, it is important that the student observe demonstrations and have an opportunity to conduct experiments. Not only will this help the student to understand and retain the course material, it will also provide the student with an opportunity to see and use modern measurement equipments and to CH3169-0/92/0000-0032 $3.00 01992 IEEE 166 obtain an appreciation for realistic \"numbers\" to be observed in practice. The objective of the proposed project is to develop a minimum of two demonstrations and four experiments for the new course which will first be taught during the spring '92 semester. If possible, a site visit by the students to the local EMC laboratory at General Electric will also be arranged. Course Description 7.2 Shielded Wires 7.3 Twisted Wires","PeriodicalId":93568,"journal":{"name":"IEEE International Symposium on Electromagnetic Compatibility : [proceedings]. 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A) PROBLEM STATEMENT The accreditation board for Electrical and Computer Engineering undergraduate programs requires that undergraduate students take a minimum of 16 design credits. Currently, Electrical and Computer Engineering students at Syracuse University have little flexibility in selection of their design courses. To alleviate this situation, it is proposed to develop a new 500-level design course to be taught for senior and first-year graduate students. In selecting the topic area for such a course, consideration was given to industrial requirements. Manufacturers of electrical products and electronic systems are keenly aware of the importance of electromagnetic compatibility (EMC). For example, it is important that the electromagnetic radiation from a home computer not interfere with television reception. As a rule, industry cannot afford an in house program to train their beginning engineers to the necessary level of EMC design competence. Consequently, industry today considers a basic knowledge of EMC to be as important a part of an Electrical or Computer Engineer’s education as is circuits, digital design, signal theory, electromagnetics, etc. Nevertheless, according to a survey in 1985 by the Education Committee of the IEEE Electromagnetic Compatibility Society, only a few colleges and universities offer courses dealing with EMC. In spite of this, most respondents felt that there was a need to include this material in the Electrical Engineering curriculum. To satisfy this need, ELECTROMAGNETIC COMPATIBILITY was selected as the subject matter for the new design course. B) OBJECTIVES The course material will be based on the text, INTRODUCTION TO ELECTROMAGNETIC COMPATIBILITY, by C.R. Paul. The manuscript has only recently been accepted for publication by John Wiley and Sons, Inc. (I served as one of the reviewers for John Wiley.) A course outline, based on this text, is included with the supporting documents. In a design course of this nature, it is important that the student observe demonstrations and have an opportunity to conduct experiments. Not only will this help the student to understand and retain the course material, it will also provide the student with an opportunity to see and use modern measurement equipments and to CH3169-0/92/0000-0032 $3.00 01992 IEEE 166 obtain an appreciation for realistic \\\"numbers\\\" to be observed in practice. The objective of the proposed project is to develop a minimum of two demonstrations and four experiments for the new course which will first be taught during the spring '92 semester. If possible, a site visit by the students to the local EMC laboratory at General Electric will also be arranged. Course Description 7.2 Shielded Wires 7.3 Twisted Wires\",\"PeriodicalId\":93568,\"journal\":{\"name\":\"IEEE International Symposium on Electromagnetic Compatibility : [proceedings]. 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引用次数: 5
摘要
《电磁兼容性》是电气工程专业500级新开设的一门课程。本课程将为电气和计算机工程专业学生提供相对较少的设计课程。它也将满足行业对了解设计电磁兼容产品相关问题的学生的需求。为了加强课程的设计方面,将包括演示和实验。A)问题说明电子与计算机工程本科专业认证委员会要求本科学生至少修满16个设计学分。目前,雪城大学(Syracuse University)电气和计算机工程专业的学生在选择设计课程时几乎没有灵活性。为了缓解这种情况,建议开发一门新的500级设计课程,面向大四和研究生一年级的学生。在为这门课程选择主题领域时,考虑到了工业要求。电气产品和电子系统的制造商都敏锐地意识到电磁兼容性(EMC)的重要性。例如,重要的是,来自家用电脑的电磁辐射不干扰电视接收。作为一个规则,行业不能负担一个内部程序来培训他们的初级工程师到必要水平的EMC设计能力。因此,当今业界认为EMC的基本知识与电路,数字设计,信号理论,电磁学等一样,是电气或计算机工程师教育的重要组成部分。然而,根据1985年IEEE电磁兼容协会教育委员会的一项调查,只有少数学院和大学提供有关电磁兼容的课程。尽管如此,大多数受访者认为有必要将这些材料纳入电气工程课程。为了满足这一需求,我们选择了电磁兼容性作为新设计课程的主题。本课程材料将基于C.R. Paul所著的《电磁兼容性导论》。手稿直到最近才被约翰·威利父子公司(John Wiley and Sons, Inc.)接受出版(我是约翰·威利的审稿人之一)。课程大纲,基于这一文本,包括在支持文件。在这种性质的设计课程中,学生观察演示并有机会进行实验是很重要的。这不仅有助于学生理解和记住课程材料,还将为学生提供一个看到和使用现代测量设备的机会,并使他们能够在实践中观察到真实的“数字”。该计划的目标是为新课程开发至少两个演示和四个实验,该课程将于1992年春季学期首次教授。如有可能,还将安排学生到当地通用电气公司的EMC实验室进行实地考察。课程介绍7.2屏蔽线7.3绞合线
ELECTROMAGNETIC COMPATIBILITY is proposed as a new 500-level course in Electrical Engineering. This course will augment the relatively few design courses available to students in Electrical and Computer Engineering. It will also satisfy the need by industry for students who understand problems associated with designing electromagnetically compatible products. To enhance the design aspect of the course, demonstrations and experiments will be included. A) PROBLEM STATEMENT The accreditation board for Electrical and Computer Engineering undergraduate programs requires that undergraduate students take a minimum of 16 design credits. Currently, Electrical and Computer Engineering students at Syracuse University have little flexibility in selection of their design courses. To alleviate this situation, it is proposed to develop a new 500-level design course to be taught for senior and first-year graduate students. In selecting the topic area for such a course, consideration was given to industrial requirements. Manufacturers of electrical products and electronic systems are keenly aware of the importance of electromagnetic compatibility (EMC). For example, it is important that the electromagnetic radiation from a home computer not interfere with television reception. As a rule, industry cannot afford an in house program to train their beginning engineers to the necessary level of EMC design competence. Consequently, industry today considers a basic knowledge of EMC to be as important a part of an Electrical or Computer Engineer’s education as is circuits, digital design, signal theory, electromagnetics, etc. Nevertheless, according to a survey in 1985 by the Education Committee of the IEEE Electromagnetic Compatibility Society, only a few colleges and universities offer courses dealing with EMC. In spite of this, most respondents felt that there was a need to include this material in the Electrical Engineering curriculum. To satisfy this need, ELECTROMAGNETIC COMPATIBILITY was selected as the subject matter for the new design course. B) OBJECTIVES The course material will be based on the text, INTRODUCTION TO ELECTROMAGNETIC COMPATIBILITY, by C.R. Paul. The manuscript has only recently been accepted for publication by John Wiley and Sons, Inc. (I served as one of the reviewers for John Wiley.) A course outline, based on this text, is included with the supporting documents. In a design course of this nature, it is important that the student observe demonstrations and have an opportunity to conduct experiments. Not only will this help the student to understand and retain the course material, it will also provide the student with an opportunity to see and use modern measurement equipments and to CH3169-0/92/0000-0032 $3.00 01992 IEEE 166 obtain an appreciation for realistic "numbers" to be observed in practice. The objective of the proposed project is to develop a minimum of two demonstrations and four experiments for the new course which will first be taught during the spring '92 semester. If possible, a site visit by the students to the local EMC laboratory at General Electric will also be arranged. Course Description 7.2 Shielded Wires 7.3 Twisted Wires