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1、来稿要求论点明确、数据可靠、逻辑严密、文字精炼,每篇论文必须包括题目、作者姓名、作者单位、单位所在地及邮政编码、摘要和关键词、正文、参考文献和第一作者及通讯作者(一般为导师)简介(包括姓名、性别、职称、出生年月、所获学位、目前主要从事的工作和研究方向),在文稿的首页地脚处注明论文属何项目、何基金(编号)资助,没有的不注明。2、论文摘要尽量写成报道性文摘,包括目的、方法、结果、结论4方面内容(100字左右),应具有独立性与自含性,关键词选择贴近文义的规范性单词或组合词(3~5个)。3、文稿篇幅(含图表)一般不超过5000字,一个版面2500字内。文中量和单位的使用请参照中华人民共和国法定计量单位最新标准。外文字符必须分清大、小写,正、斜体,黑、白体,上下角标应区别明显。4、文中的图、表应有自明性。图片不超过2幅,图像要清晰,层次要分明。5、参考文献的著录格式采用顺序编码制,请按文中出现的先后顺序编号。所引文献必须是作者直接阅读参考过的、最主要的、公开出版文献。未公开发表的、且很有必要引用的,请采用脚注方式标明,参考文献不少于3条。6、来稿勿一稿多投。收到稿件之后,5个工作日内审稿,电子邮件回复作者。重点稿件将送同行专家审阅。如果10日内没有收到拟用稿通知(特别需要者可寄送纸质录用通知),则请与本部联系确认。7、来稿文责自负。所有作者应对稿件内容和署名无异议,稿件内容不得抄袭或重复发表。对来稿有权作技术性和文字性修改,杂志一个版面2500字,二个版面5000字左右。作者需要安排版面数,出刊日期,是否加急等情况,请在邮件投稿时作特别说明。8、请作者自留备份稿,本部不退稿。9、论文一经发表,赠送当期样刊1-2册,需快递的联系本部。10、请在文稿后面注明稿件联系人的姓名、工作单位、详细联系地址、电话(包括手机)、邮编等信息,以便联系有关事宜。
Control of Parallel Inverters in Distributed AC Power Systems with Consideration of Line Impedance Effect在分布式交流电力系统中考虑连线阻抗影响时的并联逆变器控制 论文发到你的邮箱了
电气工程:1Electrical Engineering My decision to pursue graduate study in the United States is underscored by my desire to be a part of the graduate program at your institution. Purdue University offers the flexibility needed for such a vast and rapidly changing field. The research facilities and the faculty at the university are par excellent. Communications is an industry that has changed our lives. In a very short period it has changed the way we have looked at things since centuries. It is one industry that is going to shape our future for centuries to come. Hence my desire to do masters in electrical engineering with communications as my major. My interest in electronics blossomed during my high school years. It was the time when technology had begun to make an impact on the lives of people in India. Hence engineering with electronics as my major was the first choice for my undergraduate studies. Right since the beginning of my undergraduate study electronics is a subject that has fascinated me with its power of applications. The subjects that I have studied include Linear Electronics, Digital Electronics. These laid the foundation for my courses in Electronic Communication & Communication Systems at a later stage. My undergraduate studies already focus on the communications aspect of electronics. A masters degree in electrical engineering with communications as major field is the next logical step. For the past four months I have been working as a project trainee at the Indian Institute for Advanced Electronics. I am working on the design and development of a "PC Controlled Digital Serial Data Generator". This short stint has given me invaluable practical experience. It has given me the confidence to pursue a masters degree and also kindled a desire to do research. During the course of my work at IIAE, I have come across several scientists. Most of them work in different areas of communications. Interactions with them have made me realize the vastness and the scope of communications. My discussions with them convinced me that specializing in communications will suit me very well. The subject of research which interests me very much is spread spectrum communication systems. Coding theory and combinations is another research subject which arouses my curiosity. The subject Communication Theory which I am studying at present introduces these topics in theory. I am eager to find out more about the applications of coding theory to spread spectrum communication systems. In addition I have been a student member of the IEEE (Institute of Electrical and Electronics Engineers, Inc.) for the past three years. Through its workshops/seminars and publications like the 'The Spectrum' it has exposed me to a lot of emerging technologies in the field of communications. It is a strong belief in my family that the American education system has the best to offer in the whole world. This belief arises out of the experience that my parents had when they did their Masters of Science in the University of Pennsylvania during the years 1967-69. If I can get an opportunity to be a part of that intellectually stimulating environment, I am sure my talents will be put to optimal use. India is a developing country with an enormous potential in the information technology business. To serve the needs of this developing industry and more important its vast population, communications is going to become of utmost importance. Thus conditions here are very conducive to supplement my aspirations when I return after completing my graduate studies. 2Electrical Engineering As a graduate student, I will undertake research and coursework in Electrical Engineering to enhance my competencies in this field. I intend to complete my master's degree in order to pursue my doctorate. The research that I am most interested in pursuing at Northeastern University surrounds the optical properties of MEMS devices, and the development of substrate-based fast electro-optical interfaces. My interest in this area stems from my undergraduate study in MEMs development for tri-axial accelerometers. Engineering has been a key interest of mine since childhood. While still in grade school I enjoyed listening to my father, an electrical engineer, teach me about advances in technology, and was always eager to hear more. I was introduced to my first computer at the age of five, and have loved interacting with them ever since. My decision to study engineering as a career was no surprise to those who knew me. In college I found that I was always studying something I enjoyed. I believe it is because I enjoy my life and my work that I have been successful. Spending hours in the laboratory is not something that I dread, but instead I take pride in my work and its successful completion. One example of this that is still fresh in my mind is the successful design of a fully functional microprocessor in the Xilinx environment. All told, the project took over 150 hours of each design-team member's time. However, I did not look on it as a drain, but an experience for learning and a focus for my professional and technical development. When we finished the project we felt the sense of worth and pride in completion of a task that was once above our level of knowledge. Pursuing a graduate degree in the research field I have chosen also feels like a challenge, and I know that study will frustrate me at times. However, I feel that my commitment to learning will not be swayed. I feel confident in my ability to be creative in my perspective, and to persevere. My ultimate goal is to be an innovator in the field I have chosen to study. Professionalism and creativity are my most valued strengths. At the heart of my interest is the advancement of man in concert with his environment. My personal philosophy of life will matter greatly during my study and after its completion. That is why I devote time to reflection on my goals and their implications. Money has never been a motivator for my work, nor do I think it will be in the future. However, as a professional and a graduate, I realize that my earning potential will be significant. That is why I also commit myself to charity and fairness. In the past I have been a member of the Boy Scouts of America, and have achieved the rank of Eagle Scout. In the course of my experience in that organization, I learned respect and moral value. Now, as a member of the IEEE, I value my professional standing and its commensurate moral implications. Ethics in engineering is as important as technical skill, and as such I intend to uphold my own ethical obligations to the best of my ability. As a Northeastern University student, I would commit all that I have to offer to my study. I intend to pursue research in MEMS technology. At Rowan University as an undergraduate student I have already conducted some research and development of MEMS sensors for military applications, resulting in publication. An article, written by myself and my project member David Bowen and edited by our advisor Dr. Robert Krchnavek, was published in the NAVSEA Intelligent Ships Symposium Proceedings of 2001. The paper was titled "Designing a 3-Axis, Monolithic, MEMS-Based Accelerometer" and was under review for endorsement by the US Navy's NAVSEA facility in Philadelphia during that year. Building on my past success in MEMs design, I hope to advance my understanding. Through research at the graduate level, it is my hope to become familiar with, and innovate the design of MEMs Optics in hopes of creating a reliable and practical MEMs Electro-Optical Interface for use in consumer electronics. It is my hope, that through my research, optical waveguides for intradevice communication might be realized. Finally, my intent to pursue graduate study is laid plain. Study of MEMs optics is my intended focus, and I am committed to my goal. In pursuing a doctoral degree, I have closely analyzed myself to determine the reasons for my previous successes and my goals for the future. I have found that I do and have always enjoyed engineering, and that I have a strong desire to pursue my study further. I am prepared to commit myself to that study, and achieve what I have set out to do. 3I Wish to Pursue an MS Degree in Electrical Engineering During my senior year at Purdue University, I made a decision that has impacted the entire course of my education. While my classmates were making definite decisions about their career paths, I chose to implement a five-year plan of development and growth for myself. I designed this plan in order to examine various careers that I thought might interest me, as well as to expand upon my abilities at the time. As I was attaining a BS degree in Electrical Engineering, I decided to focus primarily on fields related to the VLSI (Very Large-Scale Integrated) circuits area. My main goals were either to gain work experience or to further my education by pursuing an MS degree in Electrical Engineering (MSEE). I saw an opportunity to both work and learn through employment at Xilinx Inc. Operating as a product engineer at a successful, high-tech semiconductor company has enabled me to utilize my technical and interpersonal skills in new and challenging ways. The position has also allowed me to interact with a multitude of departments including marketing, integrated circuit (IC) design, software/CAD development, manufacturing, reliability, accounting, and sales. I thus have gained an array of experience that extended beyond the parameters of my own responsibilities. In the workplace, I rely heavily upon the interpersonal techniques I developed as a counselor in a Purdue residence hall, as well as the organizational skills I had acquired through holding various leadership positions in cultural and engineering societies. I have also cultivated an interest in high-technology marketing that has continued to grow throughout my career. My experiences with Xilinx have heightened my hunger for knowledge in the VLSI field. Two months after joining the corporation, I applied to several part-time programs in the vicinity that would allow me to acquire an MSEE degree within two to three years. San Jose State seemed an ideal choice, for its evening MSEE courses would allow me to pursue two independent, full-time positions concurrently. The San Jose program has complimented my Xilinx duties well; both demand large levels of energy and enthusiasm while guiding me to my ultimate goal a high degree of education in VLSI sciences. The resources that I poured into both endeavors have reaped many gains. I have been promoted to a Product-Yield Engineering position within Xilinx's Coarse Grain Static Memory (CGSM) Product Engineering division. My extensive coursework plays a key role in my continued success at Xilinx. Relevant classes in advanced digital and analog VLSI design, as well as sub-micron ULSI technology, have allowed me to understand more completely the workings of Xilinx, a fab-less semiconductor company that also functions as a software and hardware design, testing, and marketing center. The gains in knowledge I have made through the combination of work experience and education have indeed been exponential. The academic records of my senior year at Purdue, coupled with my MSEE coursework, are ample proof of my dedication to learning. I feel I have overcome through hard work and dedication the brief "dry phase" I underwent at Purdue during the close of my sophomore and the first semester of my junior years. My performance at that time is in no way indicative of my usual achievements; they are instead the result of urgent family difficulties that required much foreign travel and serious attention to resolve. In May, I shall graduate with an MSEE degree from San Jose well ahead of my original estimates. This early graduation with Dean's Honors is the result of my firm belief in the value of diligence, as well as my renewed determination to strive for perfection in both work and school. I am now embarking on another five-year plan, during which I hope to fulfill several specific career goals. For instance, being part of a very dynamic and results-oriented Yield team at Xilinx calls for continuous development of computational and statistical techniques. The Yield team is divided to focus on specific process/fabrication issues and process (manufacturing) optimization. My own position is an integral part of the optimization group. Speed and cost issues continue to press high technology atmospheres towards optimization, probability and stochastic processes and systems, and rigorous simulations of mathematical models. The MS in EES&OR offered at your university will grant me the statistical knowledge that is crucial for process and production optimization in a fab-less environment. In addition, product engineering requires fundamental research on mathematical models for linear and non-linear programming, as well as the utilization of efficient computer software. I continuously employ the knowledge I gained at Purdue in Operations Research and advanced mathematics courses. Yet despite the value of these classes and my high performance in them, I now require further education to best fulfill my duties. An MS in the EES&OR field, will give me knowledge that is invaluable to a career in product development, project management and strategic planning. The program will allow me to improve decision-making skills in operations, strategy, and policy issues. I will strengthen my theory and application in countless areas:continuous, discrete, numerical optimization; probabilistic and stochastic processes; dynamic systems and simulation; economics, finance, and investment; decision analysis; dynamic programming and planning under uncertainty; operations and service; corporate and individual strategy; and private and public policy , the EES&OR program will not only help me to excel at Xilinx but will also further any future career. My commitment to work and education over the last three years proves that I will pursue this MS with enthusiasm and technical edge that the MS would provide is I will be working while attending Stanford, I shall mingle education with practical application, and bring to the table interesting problems from my experience and past education. Technical challenges encountered through projects in the EES&OR program will provide motivation and opportunity for methodological data collection, processing and presentation issues presented are integral to my future goals, and the management challenges raised will provide invaluable experience for professional practice. This will in turn build a solid foundation for a life-long career that can overcome any problem in decision-making. In addition, taking courses in economics, finance, and investment analysis will allow much growth of knowledge in investment issues in different industries. The EES&OR program thus appeals not only to my engineering, economics, science and mathematical background, but will compliment my technical abilities with the conceptual frameworks needed to analyze problems in operations, production, strategic planning, and marketing in the realm of emiconductor/IC/engineering systems. I feel that I am prepared to meet the challenges of the curriculum. My coursework in intermediate microeconomics and macroeconomics, international trade, operations research, linear algebra, and probabilistic methods, along with my extensive calculus background, will allow me to function well within the program. My long-term career goals include a move into marketing and product management. I believe that attaining this MS degree is the cornerstone to achieving my goals. It will give me the academic background necessary to succeed in product development, project management, and strategic planning. It will improve decision-making skills necessary for optimizing performance. The integration of two excellent programs in Economics Systems and Operations Research thus suits my current position and ties in with future goals perfectly by improving decision making in operations, strategy and policy. At present I desire to continue at Xilinx; attending a program that provides the flexibility and convenience of the SITN, is therefore imperative. Hence, being at Stanford as an HCP student alsoattracts me. I believe that Stanford is the best environment for me to achieve my goals while gaining exposure to and experience with a diverse student body and faculty. It is my belief that one continues to learn throughout one's life, and the most effective method of learning is through interaction with 's diversity offers an environment for learning, both inside and outside the classroom. I hope to share my varied knowledge with my classmates and to take from them a new understanding of topics that are foreign to me. I believe that no other school provides students with the combination of education and environment offered by Stanford. Its outstanding academic reputation, mingled with its diverse environment and thriving Bay Area location, creates an opportunity for growth that is second to none. I have many ambitions for myself as I embark on this stage of my life. I believe that an education from Stanford will provide invaluable experiences and skills that will allow me to become a successful and innovative business leader in the new millennium. 4Research Department of Biomedical Engineering is designed to research on and solve the bio-electrical and biomagnetic engineering problems in the field of biology and medicine with the aid of engineering principles and methods. Its main task is to explain, from perspective view of engineering, the biological and pathologic processes of the living organisms, especially human beings, and research on and develop the related medical devices and life science devices. Its research directions mainly include the modeling and emulation of the biological system, testing and analysis of biomedical signals, the biomedical imaging and processing , the biological effects of electromagnetic field and the development of artificial organs and medical devices, Bioengineering With the development and integration of electromagnetism, biology and medicine, biological electromagnetism exercises more and more influence on human life and health, environment protection and biological engineering. The research on electromagnetic bioengineering is a new research direction for IEECAS, mainly including research on rules of mutual influence between electromagnetic field and life matter, biological electromagnetic effect and its application in biology, medicine and medical equipment. At present, the research team has set up labs such as biological electromagnetic environment lab, biological electromagnetic signals & electromagnetic property testing lab, electromagnetic biological effect testing lab and biological electromagnetic simulation lab. It is equipped with various electrical and magnetic fields for experiments of biological electromagnetic effects, simulation software and biochemical experiment equipment. With such equipments, it can do biological electromagnetic experiments on live animals and detached live cells, detect, analyze and process the very weak biological electromagnetic signals, analyze and test live organism or detached cell under electromagnetic interaction with biochemical quantitative methods. The recent research work focuses on the effects 方向对不对,不知你要哪种,告诉我,我再接着找多的话email you
用于分布式在线UPS中的并联逆变器的一种无线控制器已经发送。
1、来稿要求论点明确、数据可靠、逻辑严密、文字精炼,每篇论文必须包括题目、作者姓名、作者单位、单位所在地及邮政编码、摘要和关键词、正文、参考文献和第一作者及通讯作者(一般为导师)简介(包括姓名、性别、职称、出生年月、所获学位、目前主要从事的工作和研究方向),在文稿的首页地脚处注明论文属何项目、何基金(编号)资助,没有的不注明。2、论文摘要尽量写成报道性文摘,包括目的、方法、结果、结论4方面内容(100字左右),应具有独立性与自含性,关键词选择贴近文义的规范性单词或组合词(3~5个)。3、文稿篇幅(含图表)一般不超过5000字,一个版面2500字内。文中量和单位的使用请参照中华人民共和国法定计量单位最新标准。外文字符必须分清大、小写,正、斜体,黑、白体,上下角标应区别明显。4、文中的图、表应有自明性。图片不超过2幅,图像要清晰,层次要分明。5、参考文献的著录格式采用顺序编码制,请按文中出现的先后顺序编号。所引文献必须是作者直接阅读参考过的、最主要的、公开出版文献。未公开发表的、且很有必要引用的,请采用脚注方式标明,参考文献不少于3条。6、来稿勿一稿多投。收到稿件之后,5个工作日内审稿,电子邮件回复作者。重点稿件将送同行专家审阅。如果10日内没有收到拟用稿通知(特别需要者可寄送纸质录用通知),则请与本部联系确认。7、来稿文责自负。所有作者应对稿件内容和署名无异议,稿件内容不得抄袭或重复发表。对来稿有权作技术性和文字性修改,杂志一个版面2500字,二个版面5000字左右。作者需要安排版面数,出刊日期,是否加急等情况,请在邮件投稿时作特别说明。8、请作者自留备份稿,本部不退稿。9、论文一经发表,赠送当期样刊1-2册,需快递的联系本部。10、请在文稿后面注明稿件联系人的姓名、工作单位、详细联系地址、电话(包括手机)、邮编等信息,以便联系有关事宜。
没有1,《中国电机工程学报》原稿要求论点明确,数据可靠,逻辑严谨,文章要精炼,每篇论文必须具体说明标题、作者姓名、作者单位、所在地和邮政编码、摘要和关键字、文本、参考资料,以及第一位作者和通信作者(通常是导师)的介绍(包括姓名、姓氏、职称、出生年月、获得的学位、现在的主要业务和研究方向)、论文是哪些项目以及哪些资金(编号)补2,《中国电机工程学报》论文摘要写成报道性摘要,包括目的、方法、结果、结论第4页(100个字左右)、独立性和自我包含,以及关键词接近文章含义的规范性单词或组合语(3至5个)。3,包含图表的《中国电机工程学报》脚本长度通常不超过5,000个单词(在布局2500个单词内)。本文量单位的使用请参考中华人民共和国法定计量单位的最新标准。外语必须区分大小写、正、斜体、黑色和白体,上下各项的标记要明确区分。4、文本的图片、表格必须不言自明。图画不超过2点,图像就要清晰,层次也要清晰。5、参考文献的记载格式采用顺序编码,请按照本文件出现的顺序编号。引用的文献必须是作者亲自参考的、最主要的、公开出版的文献。未公开,需要引用的话,请用脚注标记3份以上的参考文献。6、原告不要再投票。收到原稿后5个工作日内审阅,通过电子邮件回复作者。主稿将派同事专家审阅。如果10天内没有收到提案通知(特别请求者可能会发送纸张招聘通知),请与本总部联系以确认。7、原告的责任是自食恶果。所有作者对原告的内容和签名没有异议,原告的内容不得抄袭或重复刊登。书稿有权技术修改,每页2500字,每页5000字左右。如果作者需要安排布局数量、出版日期、快递与否等,请给我们投邮时的特别指示。8、请作者留下备份稿,本部不退稿。9、论文发表后,赠送1-2本糖月刊,需要快递
ieee论文的参考文献格式
IEEE一般指电气和电子工程师协会。下面,我为大家分享ieee论文的参考文献格式,希望对大家有所帮助!
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[1] 白莉娟. 基于脑机接口的资源管理器[D]. 华南理工大学 2014
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[4] 李兴锋. 基于S-57国际标准的电子海图显示与导航系统[D]. 西安电子科技大学 2007
[5] 孙小平. 嵌入式IPv6实时通信技术的研究[D]. 西安电子科技大学 2007
[6] 黄晓曦. 基于SOPC的1553B总线接口的研究与设计[D]. 福州大学 2010
[7] 林嘉洪. 基于ARM和FPGA的数控系统人机接口设计[D]. 华南理工大学 2014
[8] 刘勇杰. 面向手机应用的TFT-LCD驱动芯片版图设计[D]. 天津大学 2013
[9] 罗波. 基于XDSP64的多接口仿真平台设计与实现[D]. 国防科学技术大学 2012
[10] 马俊. 数字视频接口(DVI)发送器的设计与实现[D]. 国防科学技术大学 2013
[11] 陈锦葵. 网络管理系统中拓扑发现算法的研究[D]. 西安电子科技大学 2007
[12] 王珠珠. 嵌入式操作系统裁剪技术研究[D]. 西安电子科技大学 2007
[13] 袁小勇. 电子海图无缝拼接显示技术研究[D]. 西安电子科技大学 2007
[14] 何继成,王厚生,陈长敏. 打印机IEEE1284并行接口的设计[J]. 计算机工程. 1998(12)
[15] 侯伯亨,李伯成编着.十六位微型计算机原理及接口技术[M]. 西安电子科技大学出版社, 1992
[1] 安笑蕊. 电能路由器的研究与应用[D]. 天津大学 2014
[2] 黄鑫,王永福,张道农,李芹,卞宝银. 智能变电站IEC61588时间同步系统与安全评估[J]. 电力系统自动化. 2012(13)
[3] 许铁峰,徐习东. 高可用性无缝环网在数字化变电站通信网络的应用[J]. 电力自动化设备. 2011(10)
[4] 谢志迅,邓素碧,臧德扬. 数字化变电站通信网络冗余技术[J]. 电力自动化设备. 2011(09)
[5] 唐敏. 基于OMNeT++的INET框架消息传递研究[J]. 电脑与信息技术. 2011(01)
[6] 李永亮,李刚. IEC61850第2版简介及其在智能电网中的应用展望[J]. 电网技术. 2010(04)
[7] 王洋. 电信网中基于IEEE 1588标准的时钟同步研究[D]. 浙江大学 2010
[8] 叶卫东,张润东. IEEE 1588精密时钟同步协议版本浅析[J]. 测控技术. 2010(02)
[9] 余贻鑫,栾文鹏. 智能电网述评[J]. 中国电机工程学报. 2009(34)
[10] 熊瑞辉. 多传感器系统在智能轮胎中的应用[D]. 天津大学 2014
[11] 刘建才. 基于PVDF多传感器的轮胎防抱死仿真研究[D]. 天津大学 2012
[12] 庾智兰,李智. 精确时钟同步协议最佳主时钟算法[J]. 电力自动化设备. 2009(11)
[13] 李振杰,袁越. 智能微网--未来智能配电网新的组织形式[J]. 电力系统自动化. 2009(17)
[14] 胡巨,高新华. SNTP对时方式在数字化变电站中应用[J]. 电力自动化设备. 2009(03)
[15] Song Ye. Beidou Time Synchronization Receiver for Smart Grid[J]. Energy Procedia . 2011
1、来稿要求论点明确、数据可靠、逻辑严密、文字精炼,每篇论文必须包括题目、作者姓名、作者单位、单位所在地及邮政编码、摘要和关键词、正文、参考文献和第一作者及通讯作者(一般为导师)简介(包括姓名、性别、职称、出生年月、所获学位、目前主要从事的工作和研究方向),在文稿的首页地脚处注明论文属何项目、何基金(编号)资助,没有的不注明。2、论文摘要尽量写成报道性文摘,包括目的、方法、结果、结论4方面内容(100字左右),应具有独立性与自含性,关键词选择贴近文义的规范性单词或组合词(3~5个)。3、文稿篇幅(含图表)一般不超过5000字,一个版面2500字内。文中量和单位的使用请参照中华人民共和国法定计量单位最新标准。外文字符必须分清大、小写,正、斜体,黑、白体,上下角标应区别明显。4、文中的图、表应有自明性。图片不超过2幅,图像要清晰,层次要分明。5、参考文献的著录格式采用顺序编码制,请按文中出现的先后顺序编号。所引文献必须是作者直接阅读参考过的、最主要的、公开出版文献。未公开发表的、且很有必要引用的,请采用脚注方式标明,参考文献不少于3条。6、来稿勿一稿多投。收到稿件之后,5个工作日内审稿,电子邮件回复作者。重点稿件将送同行专家审阅。如果10日内没有收到拟用稿通知(特别需要者可寄送纸质录用通知),则请与本部联系确认。7、来稿文责自负。所有作者应对稿件内容和署名无异议,稿件内容不得抄袭或重复发表。对来稿有权作技术性和文字性修改,杂志一个版面2500字,二个版面5000字左右。作者需要安排版面数,出刊日期,是否加急等情况,请在邮件投稿时作特别说明。8、请作者自留备份稿,本部不退稿。9、论文一经发表,赠送当期样刊1-2册,需快递的联系本部。10、请在文稿后面注明稿件联系人的姓名、工作单位、详细联系地址、电话(包括手机)、邮编等信息,以便联系有关事宜。
1、设置段前12pt2、在首行前增加一空行,设置字体的大小为12pt
1、来稿要求论点明确、数据可靠、逻辑严密、文字精炼,每篇论文必须包括题目、作者姓名、作者单位、单位所在地及邮政编码、摘要和关键词、正文、参考文献和第一作者及通讯作者(一般为导师)简介(包括姓名、性别、职称、出生年月、所获学位、目前主要从事的工作和研究方向),在文稿的首页地脚处注明论文属何项目、何基金(编号)资助,没有的不注明。2、论文摘要尽量写成报道性文摘,包括目的、方法、结果、结论4方面内容(100字左右),应具有独立性与自含性,关键词选择贴近文义的规范性单词或组合词(3~5个)。3、文稿篇幅(含图表)一般不超过5000字,一个版面2500字内。文中量和单位的使用请参照中华人民共和国法定计量单位最新标准。外文字符必须分清大、小写,正、斜体,黑、白体,上下角标应区别明显。4、文中的图、表应有自明性。图片不超过2幅,图像要清晰,层次要分明。5、参考文献的著录格式采用顺序编码制,请按文中出现的先后顺序编号。所引文献必须是作者直接阅读参考过的、最主要的、公开出版文献。未公开发表的、且很有必要引用的,请采用脚注方式标明,参考文献不少于3条。6、来稿勿一稿多投。收到稿件之后,5个工作日内审稿,电子邮件回复作者。重点稿件将送同行专家审阅。如果10日内没有收到拟用稿通知(特别需要者可寄送纸质录用通知),则请与本部联系确认。7、来稿文责自负。所有作者应对稿件内容和署名无异议,稿件内容不得抄袭或重复发表。对来稿有权作技术性和文字性修改,杂志一个版面2500字,二个版面5000字左右。作者需要安排版面数,出刊日期,是否加急等情况,请在邮件投稿时作特别说明。8、请作者自留备份稿,本部不退稿。9、论文一经发表,赠送当期样刊1-2册,需快递的联系本部。10、请在文稿后面注明稿件联系人的姓名、工作单位、详细联系地址、电话(包括手机)、邮编等信息,以便联系有关事宜。
ieee论文的参考文献格式
IEEE一般指电气和电子工程师协会。下面,我为大家分享ieee论文的参考文献格式,希望对大家有所帮助!
[1] 姚芝凤. 磁悬浮机床主轴控制方法的研究[D]. 天津大学 2007
[2] 程晓菊. SAE J1939网络管理协议的实现及应用研究[D]. 天津大学 2007
[3] 陈振东. 载重轮胎动平衡实验机若干关键技术的研究[D]. 天津大学 2007
[4] 关静. MicroCANopen协议栈的实现及应用研究[D]. 天津大学 2007
[5] 宋爱玲. 一种基于PEGASIS的无线传感网链式分层路由协议[D]. 南京邮电大学 2014
[6] 宋俊毅. 轻量级IPSec协议一致性测试研究[D]. 南京邮电大学 2014
[7] 王会利. 载重轮胎动平衡机的研究[D]. 天津大学 2008
[8] 陈溪. 未来网络组件行为的动态感知与组件聚类机制研究[D]. 南京邮电大学 2014
[9] 王珠珠. 嵌入式操作系统裁剪技术研究[D]. 西安电子科技大学 2007
[10] 刘兴贵. 容迟与容断网络中信任协作机制的研究[D]. 南京邮电大学 2014
[11] 钱雅秋. 无线传感器网络中的Sybil攻击防御与检测技术研究[D]. 南京邮电大学 2014
[12] 窦轶. 无线传感器网络隐私数据查询技术研究[D]. 南京邮电大学 2014
[13] 汪凯. 基于智慧物流平台的安全通信协议的实现与应用[D]. 南京邮电大学 2014
[14] 宋柳柳. 基于动态层的簇间路由协议DLCR的.研究与仿真[D]. 南京邮电大学 2014
[15] 孙皓. 统一通信系统规划与实施[D]. 南京邮电大学 2014
[1] 白莉娟. 基于脑机接口的资源管理器[D]. 华南理工大学 2014
[2] 徐发荣,张涛,高建卫. 一种基于W91284PIC的外设端双向并口设计[J]. 国外电子元器件. 2001(05)
[3] 邹志成. 应急响应联动系统模型的研究和典型工具的建立[D]. 西安电子科技大学 2006
[4] 李兴锋. 基于S-57国际标准的电子海图显示与导航系统[D]. 西安电子科技大学 2007
[5] 孙小平. 嵌入式IPv6实时通信技术的研究[D]. 西安电子科技大学 2007
[6] 黄晓曦. 基于SOPC的1553B总线接口的研究与设计[D]. 福州大学 2010
[7] 林嘉洪. 基于ARM和FPGA的数控系统人机接口设计[D]. 华南理工大学 2014
[8] 刘勇杰. 面向手机应用的TFT-LCD驱动芯片版图设计[D]. 天津大学 2013
[9] 罗波. 基于XDSP64的多接口仿真平台设计与实现[D]. 国防科学技术大学 2012
[10] 马俊. 数字视频接口(DVI)发送器的设计与实现[D]. 国防科学技术大学 2013
[11] 陈锦葵. 网络管理系统中拓扑发现算法的研究[D]. 西安电子科技大学 2007
[12] 王珠珠. 嵌入式操作系统裁剪技术研究[D]. 西安电子科技大学 2007
[13] 袁小勇. 电子海图无缝拼接显示技术研究[D]. 西安电子科技大学 2007
[14] 何继成,王厚生,陈长敏. 打印机IEEE1284并行接口的设计[J]. 计算机工程. 1998(12)
[15] 侯伯亨,李伯成编着.十六位微型计算机原理及接口技术[M]. 西安电子科技大学出版社, 1992
[1] 安笑蕊. 电能路由器的研究与应用[D]. 天津大学 2014
[2] 黄鑫,王永福,张道农,李芹,卞宝银. 智能变电站IEC61588时间同步系统与安全评估[J]. 电力系统自动化. 2012(13)
[3] 许铁峰,徐习东. 高可用性无缝环网在数字化变电站通信网络的应用[J]. 电力自动化设备. 2011(10)
[4] 谢志迅,邓素碧,臧德扬. 数字化变电站通信网络冗余技术[J]. 电力自动化设备. 2011(09)
[5] 唐敏. 基于OMNeT++的INET框架消息传递研究[J]. 电脑与信息技术. 2011(01)
[6] 李永亮,李刚. IEC61850第2版简介及其在智能电网中的应用展望[J]. 电网技术. 2010(04)
[7] 王洋. 电信网中基于IEEE 1588标准的时钟同步研究[D]. 浙江大学 2010
[8] 叶卫东,张润东. IEEE 1588精密时钟同步协议版本浅析[J]. 测控技术. 2010(02)
[9] 余贻鑫,栾文鹏. 智能电网述评[J]. 中国电机工程学报. 2009(34)
[10] 熊瑞辉. 多传感器系统在智能轮胎中的应用[D]. 天津大学 2014
[11] 刘建才. 基于PVDF多传感器的轮胎防抱死仿真研究[D]. 天津大学 2012
[12] 庾智兰,李智. 精确时钟同步协议最佳主时钟算法[J]. 电力自动化设备. 2009(11)
[13] 李振杰,袁越. 智能微网--未来智能配电网新的组织形式[J]. 电力系统自动化. 2009(17)
[14] 胡巨,高新华. SNTP对时方式在数字化变电站中应用[J]. 电力自动化设备. 2009(03)
[15] Song Ye. Beidou Time Synchronization Receiver for Smart Grid[J]. Energy Procedia . 2011
没有1,《中国电机工程学报》原稿要求论点明确,数据可靠,逻辑严谨,文章要精炼,每篇论文必须具体说明标题、作者姓名、作者单位、所在地和邮政编码、摘要和关键字、文本、参考资料,以及第一位作者和通信作者(通常是导师)的介绍(包括姓名、姓氏、职称、出生年月、获得的学位、现在的主要业务和研究方向)、论文是哪些项目以及哪些资金(编号)补2,《中国电机工程学报》论文摘要写成报道性摘要,包括目的、方法、结果、结论第4页(100个字左右)、独立性和自我包含,以及关键词接近文章含义的规范性单词或组合语(3至5个)。3,包含图表的《中国电机工程学报》脚本长度通常不超过5,000个单词(在布局2500个单词内)。本文量单位的使用请参考中华人民共和国法定计量单位的最新标准。外语必须区分大小写、正、斜体、黑色和白体,上下各项的标记要明确区分。4、文本的图片、表格必须不言自明。图画不超过2点,图像就要清晰,层次也要清晰。5、参考文献的记载格式采用顺序编码,请按照本文件出现的顺序编号。引用的文献必须是作者亲自参考的、最主要的、公开出版的文献。未公开,需要引用的话,请用脚注标记3份以上的参考文献。6、原告不要再投票。收到原稿后5个工作日内审阅,通过电子邮件回复作者。主稿将派同事专家审阅。如果10天内没有收到提案通知(特别请求者可能会发送纸张招聘通知),请与本总部联系以确认。7、原告的责任是自食恶果。所有作者对原告的内容和签名没有异议,原告的内容不得抄袭或重复刊登。书稿有权技术修改,每页2500字,每页5000字左右。如果作者需要安排布局数量、出版日期、快递与否等,请给我们投邮时的特别指示。8、请作者留下备份稿,本部不退稿。9、论文发表后,赠送1-2本糖月刊,需要快递
ieee论文的参考文献格式
IEEE一般指电气和电子工程师协会。下面,我为大家分享ieee论文的参考文献格式,希望对大家有所帮助!
[1] 姚芝凤. 磁悬浮机床主轴控制方法的研究[D]. 天津大学 2007
[2] 程晓菊. SAE J1939网络管理协议的实现及应用研究[D]. 天津大学 2007
[3] 陈振东. 载重轮胎动平衡实验机若干关键技术的研究[D]. 天津大学 2007
[4] 关静. MicroCANopen协议栈的实现及应用研究[D]. 天津大学 2007
[5] 宋爱玲. 一种基于PEGASIS的无线传感网链式分层路由协议[D]. 南京邮电大学 2014
[6] 宋俊毅. 轻量级IPSec协议一致性测试研究[D]. 南京邮电大学 2014
[7] 王会利. 载重轮胎动平衡机的研究[D]. 天津大学 2008
[8] 陈溪. 未来网络组件行为的动态感知与组件聚类机制研究[D]. 南京邮电大学 2014
[9] 王珠珠. 嵌入式操作系统裁剪技术研究[D]. 西安电子科技大学 2007
[10] 刘兴贵. 容迟与容断网络中信任协作机制的研究[D]. 南京邮电大学 2014
[11] 钱雅秋. 无线传感器网络中的Sybil攻击防御与检测技术研究[D]. 南京邮电大学 2014
[12] 窦轶. 无线传感器网络隐私数据查询技术研究[D]. 南京邮电大学 2014
[13] 汪凯. 基于智慧物流平台的安全通信协议的实现与应用[D]. 南京邮电大学 2014
[14] 宋柳柳. 基于动态层的簇间路由协议DLCR的.研究与仿真[D]. 南京邮电大学 2014
[15] 孙皓. 统一通信系统规划与实施[D]. 南京邮电大学 2014
[1] 白莉娟. 基于脑机接口的资源管理器[D]. 华南理工大学 2014
[2] 徐发荣,张涛,高建卫. 一种基于W91284PIC的外设端双向并口设计[J]. 国外电子元器件. 2001(05)
[3] 邹志成. 应急响应联动系统模型的研究和典型工具的建立[D]. 西安电子科技大学 2006
[4] 李兴锋. 基于S-57国际标准的电子海图显示与导航系统[D]. 西安电子科技大学 2007
[5] 孙小平. 嵌入式IPv6实时通信技术的研究[D]. 西安电子科技大学 2007
[6] 黄晓曦. 基于SOPC的1553B总线接口的研究与设计[D]. 福州大学 2010
[7] 林嘉洪. 基于ARM和FPGA的数控系统人机接口设计[D]. 华南理工大学 2014
[8] 刘勇杰. 面向手机应用的TFT-LCD驱动芯片版图设计[D]. 天津大学 2013
[9] 罗波. 基于XDSP64的多接口仿真平台设计与实现[D]. 国防科学技术大学 2012
[10] 马俊. 数字视频接口(DVI)发送器的设计与实现[D]. 国防科学技术大学 2013
[11] 陈锦葵. 网络管理系统中拓扑发现算法的研究[D]. 西安电子科技大学 2007
[12] 王珠珠. 嵌入式操作系统裁剪技术研究[D]. 西安电子科技大学 2007
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