有关自动化英语的论文题目

有关自动化英语的论文题目

用于分布式在线UPS中的并联逆变器的一种无线控制器A Wireless Controller for Parallel Inverters in Distributed Online UPS SystemsJosep M. Guerrero', Luis Garcia de Vicufia", Jose Matas'*, Jaume Miret", and Miguel Castilla". Departament #Enginyeria de Sistemes, Automatica i Informhtica Industrial. Universitat Polithica de CatalunyaC. Comte d'Urgell, -Barcelona. Spain. Email: .. Departament #Enginyeria Electrbnica. Universitat Polit6cnica de CatalunyaAV. Victor BaLguer s/n. 08800I - Vilanova i la Geltrh. SpainAbsiract - In this paper, a novel controller for parallelconnectedonline-UPS inverters without control wireinterconnections is presented. The wireless control technique isbased on the well-known droop method, which consists inintroducing P-oand Q-V schemes into the inverters, in order toshare properly the power drawn to the loads. The droop methodhas been widely used in applications of load sharing betweendifferent parallel-connected inverters. However, this methodhas several drawbacks that limited its application, such as atrade-off between output-voltage regulation and power sharingaccuracy, slow transient response, and frequency and phasedeviation. This last disadvantage makes impracticable themethod in online-UPS systems, since in this case every modulemust be in phase with the utility ac mains. To overcome theselimitations, we propose a novel control scheme, endowing to theparalleled-UPS system a proper transient response, strictlyfrequency and phase synchronization with the ac mains, andexcellent power sharing. Simulation and experimental resultsare reported confirming the validity of the proposed . INTRODUCTIONThe parallel operation of distributed Uninterruptible PowerSupplies (UPS) is presented as a suitable solution to supplycritical and sensitive loads, when high reliability and poweravailability are required. In the last years, many controlschemes for parallel-connected inverters has been raised,which are derived from parallel-schemes of dc-dc converters[I], such as the master-slave control [2], or the democraticcontrol [3]. In contrast, novel control schemes have beenappeared recently, such as the chain-structure control [4], orthe distributed control [ 5 ] . However, all these schemes needcontrol interconnections between modules and, hence, thereliability of the system is reduced since they can be a sourceof noise and failures. Moreover, these communication wireslimited the physical situation ofthe modules [6].In this sense, several control techniques has been proposedwithout control interconnections, such as the droop this method, the control loop achieves good power sharingmaking tight adjustments over the output voltage frequencyand amplitude of the inverter, with the objective tocompensate the active and reactive power unbalances [7].This concept is derived from the power system theory, inwhich the frequency of a generator drops when the powerdrawn to the utility line increases [8].0-7803-7906-3/03/$ 02003 IEEE. 1637However, this control approach has an inherent trade-offbetween voltage regulation and power sharing. In addition,this method exhibits slow dynamic-response, since it requireslow-pass filters to calculate the average value of the activeand reactive power. Hence, the stability and the dynamics ofthe whole system are hardly influenced by the characteristicsof these filters and by the value of the droop coefficients,which are bounded by the maximum allowed deviations ofthe output voltage amplitude and , when active power increases, the droopcharacteristic causes a frequency deviation from the nominalvalue and, consequently, it results in a variable phasedifference between the mains and the inverter output fact can be a problem when the bypass switch mustconnect the utility line directly to the critical bus in stead ofits phase difference. In [9], two possibilities are presented inorder to achieve phase synchronization for parallel lineinteractiveUPS systems. The first one is to locate a particularmodule near the bypass switch, which must to synchronizethe output voltage to the mains while supporting overloadcondition before switch on. The second possibility is to waitfor the instant when phase matching is produced to connectthe , the mentioned two folds cannot be applied to aparallel online-UPS system, since maximum transfer timeought to be less than a % of line period, and all the modulesmust be always synchronized with the mains when it ispresent. Hence, the modules should be prepared to transferdirectly the energy from the mains to the critical bus in caseof overload or failure [lo].In our previous works [11][12], we proposed differentcontrol schemes to overcome several limitations of theconventional droop method. However, these controllers bythemselves are inappropriate to apply to a parallel online-UPS system. In this paper, a novel wireless control scheme isproposed to parallel different online UPS modules with highperformance and restricted requirements. The controllerprovides: 1) proper transient response; 2) power sharingaccuracy; 3) stable frequency operation; and 4) good phasematching between the output-voltage and the utility , this new approach is especially suitable for paralleled-UPS systems with true redundancy, high reliability andpower availability. Simulation and experimental results arereported, confirming the validity of this control . 1. Equivalenl cimuif ofan invener connecled 10 a bust"Fig. 2. P-odraop . REVlEW OF THE CONVENTIONAL DROOP METHODFig. 1 shows the equivalent circuit of an inverter connectedto a common bus through coupled impedance. When thisimpedance is inductive, the active and reactive powers drawnto the load can be expressed asEVcosQ - V2 Q=where Xis the output reactance of an inverter; Q is the phaseangle between the output voltage of the inverter and thevoltage of the common bus; E and V are the amplitude of theoutput voltage of the inverter and the bus voltage, the above equations it can be derived that the activepower P is predominately dependent on the power angle Q,while the reactive power Q mostly depends on the outputvoltageamplitude. Consequently, most of wireless-control ofparalleled-inverters uses the conventional droop method,which introduces the following droops in the amplitude Eand the frequency U of the inverter output voltageu = w -mP (3)E = E ' - n Q , (4)being W* and E' the output voltage frequency and amplitudeat no load, respectively; m and n are the droop coefficientsfor the frequency and amplitude, , a coupled inductance is needed between theinverter output and the critical bus that fixes the outputimpedance, in order to ensure a proper power flow. However,it is bulky and increase:; the size and the cost of the UPSmodules. In addition, tho output voltage is highly distortedwhen supplying nonlinezr loads since the output impedanceis a pure is well known that if droop coefficients are increased,then good power sharing is achieved at the expense ofdegrading the voltage regulation (see Fig. 2).The inherent trade-off of this scheme restricts thementioned coefficients, which can be a serious limitation interms of transient response, power sharing accuracy, andsystem the other hand, lo carry out the droop functions,expressed by (3) and (4), it is necessary to calculate theaverage value over one line-cycle of the output active andreactive instantaneous power. This can be implemented bymeans of low pass filters with a smaller bandwidth than thatof the closed-loop inverter. Consequently, the powercalculation filters and droop coefficients determine, to a largeextent, the dynamics and the stability of the paralleledinvertersystem [ conclusion, the droop method has several intrinsicproblems to be applied a wireless paralleled-system ofonline UPS, which can he summed-up as follows:Static trade-off between the output-voltage regulation(frequency and amplitude) and the power-sharingaccuracy (active an4d reactive).2) Limited transient response. The system dynamicsdepends on the power-calculation filter characteristics,the droop coefficients, and the output of ac mains synchronization. The frequency andphase deviations, due to the frequency droop, makeimpracticable this method to a parallel-connectedonline UPS system, in which every UPS should becontinuously synchronized to the public ac )3)111. PROPOSED CONTROL FOR PARALLEL ONLINE UPSINVERTERSIn this work, we will try to overcome the above limitationsand to synthesize a novel control strategy withoutcommunication wires that could be appropriate to highperformanceparalleled industrial UPS. The objective is toconnect online UPS inverters in parallel without usingcontrol interconnections. This kind of systems, also namedinverter-preferred, should be continuously synchronized tothe utility line. When an overload or an inverter failureoccurs, a static bypass switch may connect the input line tothe load, bypassing the inve:rter [14][15].Fig. 3 shows the general diagram of a distributed onlineUPS system. This system consists of two buses: the utilitybus, which is connected lo the public ac mains; and thesecure bus, connected to the distributed critical loads. Theinterface between these buses is based on a number of onlineUPS modules connected in parallel, which providescontinuously power to the: loads [16]. The UPS modulesinclude a rectifier, a set of batteries, an inverter, and a staticbypass ac mainsutility busI I Ij distributed loads !Fig. 3. Online distributed UPS /I 4(4Fig. 4. Operation modes of an online UPS.(a) Normal operation. (b) Bypass operation. (c) Mains failureThe main operation modes of a distributed online UPS1) Normal operation: The power flows to the load, fromthe utility through the distributed UPS ) Mains failure: When the public ac mains fails, theUPS inverters supply the power to the loads, from thebatteries, without operation: When an overload situation occurs,the bypass switch must connect the critical busdirectly to the ac mains, in order to guarantee thecontinuous supply of the loads, avoiding the damageof the UPS this reason, the output-voltage waveform should besynchronized to the mains, when this last is are listed below (see Fig. 5):3)Nevertheless, as we state before, the conventional droopmethod can not satisfy the need for synchronization with theutility, due to the frequency variation of the inverters, whichprovokes a phase obtain the required performance, we present a transientP-w droop without frequency-deviation in steady-state,proposed previously by OUT in [ 111w=o -mP (5)where is the active power signal without the dccomponent,which is done by. -I t -1sP= p ,( s + t - ' ) ( s + o , )being zthe time constant of the transient droop transient droop function ensures a stable frequencyregulation under steady-state conditions, and 'at the sametime, achieves active power balance by adjusting thefrequency of the modules during a load transient. Besides, toadjust the phase of the modules we propose an additionalsynchronizing loop, yieldingo=w'-m%k,A$, (7)where A$ is the phase difference between the inverter and themains; and k, is the proportional constant of the frequencyadjust. The steady-state frequency reference w* can beobtained by measuring the utility line second term of the previous equality trends to zero insteady state, leading tow = w' - k4($ -@'), (8)being $and $* the phase angles of the output voltage inverterand the utility mains, into account that w = d $ / d t , we can obtain thenext differential equation, which is stable fork, positived$ *dt dt- + km$ = - + k,$' . (9)Thus, when phase difference increases, frequency willdecrease slightly and, hence, all :he UPS modules will besynchronized with the utility, while sharing the power drawnto the . CONTROLLIEMRP LEMENTATIONFig. 5 depicts the block diagram of the proposedcontroller. The average active power P , without the dccomponent, can be obtained by means of multiplying theoutput voltage by the output current, and filtering the product........................................................................................io",.LSj'nchronirorion loop.......................................................................................Fig. 5. Block diagram of the proposed a band-pass filter. In a similar way, the averagereactive power is obtained, hut in this case the output-voltagemust be delayed 90 degrees, and using a low-pass order to adjust the output voltage frequency, equation(7) is implemented, which corresponds to the frequencymains drooped by two transient-terms: the transient activepower signal term; and the phase difference term, whichis added in order to synchronize the output voltage with theac mains, in a phase-locked loop (PLL) fashion. The outputvoltageamplitude is regulated by using the conventionaldroop method (4).Finally, the physical coupled inductance can be avoided byusing a virtual inductor [17]. This concept consists inemulated an inductance behavior, by drooping the outputvoltage proportionally to the time derivative of the outputcurrent. However, when supplying nonlinear loads, the highordercurrent-harmonics can increase too much the outputvoltageTHD. This can be easily solved by using a high-passfilter instead of a pure-derivative term of the output current,which is useful to share linear and nonlinear loads [I 1][12].Furthermore, the proper design of this output inductance canreduce, to a large extent, the unbalance line-impedanceimpact over the power sharing . SIMULATION AND EXPERIMENTARELS ULTSThe proposed control scheme, (4) and (7), was simulatedwith the parameters listed in Table 1 and the scheme shownin Fig. 6, for a two paralleled inverters system. Thecoefficients m, n, T, and kv were chosen to ensure stability,proper transient response and good phase matching. Fig. 7shows the waveforms of the frequency, circulating currents,phase difference between the modules and the utility line,and the evolution of the active and reactive powers. Note theexcellent synchronization between the modules and theACmiiinr 4 j. ...L...... ..........................B...u...n...... ................................... iFig. 6. Parallel operation oftwa online UPS modules,mains, and, at the same time, the good power sharingobtained. This characteristik let us to apply the controller tothe online UPS paralleled I-kVA UPS modules were built and tested in order toshow the validity of the proposed approach. Each UPSinverter consisted of a single-phase IGBT full-bridge with aswitching frequency of 20 kHz and an LC output filter, withthe following parameters: 1. = 1 mH, C = 20 WF, Vi" = 400V,v, = 220 V, I50 Hz. The controllers of these inverters werebased on three loops: an inner current-loop, an outer PIcontroller that ensures voltage regulation, and the loadsharingcontroller, based on (4) and (7). The last controllerwas implemented by means of a TMS320LF2407A, fixedpoint40 MHz digital sigrial processor (DSP) from TexasInstruments (see Fig. 8), using the parameters listed in TableI. The DSP-controller also includes a PLL block in order tosynchronize the inverter with the common bus. When thisoccurs, the static bypass switch is tumed on, and the droopbasedcontrol is 7 Wa\cfc)rms for , ;mnectcd in parallel. rpchrontred io Ihc ac mdnl.(a) Frequencics ufhoth UPS (b) Clrculattng currcni among modulcs. (CJ Phmc d!Nercn;: betucen ihc UPS a#>dth e ai mum(d) Ikiril uf the phze diNmncc (e) md (0 Activc and rcactlw pouerr "I ooih UPSNote that the iimc-acs arc deliheratcly JiNercni due in thc disiinct timuion*uni) ofthe \ THE PARALLELESDYS Order I IFilter Cut-off Frequency I 0, I 10 I ragsFig. 8 shows the output-current transient response of theUPS inverters. First, the two UPS are operating in parallelwithout load. Notice that a small reactive current is circlingbetween the modules, due to the measurement , a nonlinear load, with a crest factor of 3, is connectedsuddenly. This result shows the good dynamics and loadsharingof the paralleled system when sharing a . 8. Output current for the two paralleled UPS, during the connection of Bcommon nonlinear load with a crest factor of 3. (Axis-x: 20 mddiv. Axis-y:5 Mdiv.).VI. CONCLUSIONSIn this paper, a novel load-sharing controller for parallelconnectedonline UPS systems, was proposed. The controlleris based on the droop method, which avoids the use ofcontrol interconnections. In a sharp contrast with theconventional droop method, the controller presented is ableto keep the output-voltage frequency and phase strictlysynchronized with the utility ac mains, while maintaininggood load sharing for linear and nonlinear loads. This fact letus to extend the droop method to paralleled online the other hand, the proposed controller emulates aspecial kind of impedance, avoiding the use of a physicalcoupled inductance. results reported here show theeffectiveness of the proposed approach.

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。

办公自动化系统是人机信息系统，是办公自动化技术与管理科学、行为科学、组织理论等相融合，贯穿到办公活动的各个方面，并对这些方面产生一系列影响之后形成的系统，其目的是尽可能充分利用信息资源，提高办公质量和办公效率。 办公自动化系统是一种人机信息系统，具有一般信息系统的共性。同时，由于办公过程和办公活动具不有确定性，人在系统中应始终处于主导地位。办公的主体是办公人员，设备只是服务于人的技术手段。建立办公自动化系统后，人的办公活动和社会组织的办公过程已离不开设备的运行，而是与其结合在一起形成一个统一的系统。建立办公自动化系统的目的并不单纯是提高办公效率或减少办公人员，而首先是为了提高办公质量，在提高办公质量和办公效率的基础上，通过各种决策模型及时提供辅助决策的信息，以实现科学管理和科学决策。此外，办公自动化系统是一个开放式的系统。在设计和建立系统时，应充分考虑和社会环境的连接。办公自动化系统的功能与办公室自动化的功能概念上存在差别。办公室自动化功能通常指办公室中配备具有自动化功能的设备，这些设备能使某些办公活动自动化或实现某个单位业务的自动化处理；而办公自动化系统则是在办公室自动化功能的基础上发展起来，以办公自动化技术为主体，同人、组织、制度、环境等相结合的完整的系统。

算了吧 你还是去买吧 200快左右的样子 那些论文都有的 你可以查下的

与自动化有关的英文论文题目

不会写论文还这么嚣张?不就是250分吗得到了又怎么地？能吃呀？

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

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。

什么意思？要英文的？题目要汉语翻译？

有关自动化专业的英文论文题目

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

我有一篇我本科毕设的小论文，英文中文都有，而且是我人工翻译的，8000字左右。你要的话PM我。我是电气工程及其自动化专业的。《Analysis of thyristor-controlled phase shifter applied in damping power system oscillations》

我可以给你 +471903103 专业论文及翻译，还有CAD图形。

自动化相关的论文题目

自动化是一门涉及学科较多、应用广泛的综合性科学技术。作为一个系统工程，它由5个单元组成。下面，我为大家分享自动化相关的论文题目，希望对大家有所帮助！

.自动化专业人才培养探索

.自动化流水线实训系统的设计

.电力自动化继电保护的安全管理

.浅析电气自动化控制系统的设计思想

.基于PLC的工业自动化控制技术探讨

.工业自动化控制技术向智能家居的演进

.矿井主扇风机自动化与信息化改造

.基于IEC的变电站自动化系统安全风险评估

.浅析集控站综合自动化系统运行中存在的问题

.数字化变电站自动化技术的应用

.如何提高综合自动化变电站的抗电磁干扰能力

.自动化专业人才培养方案和课程体系的改革与实践

.配电网自动化技术问题初探

.楼宇自动化系统的监控方式及节能分析

.地铁自动化控制相关系统的对比及应用

.基于调度策略的自动化仓库系统优化问题研究

.基于组态软件的综合自动化平台的设计与实现

.基于PLC和运动控制器的电气自动化实验平台的设计

.矿井自动化项目技术管理模式浅论

.铁路变电站自动化监控系统的研制

.馈线自动化自适应快速保护控制方案

.高速制管机上的自动化系统解决方案

.智能变电站是变电站综合自动化的发展目标

.煤矿自动化与信息化技术回顾与展望

.以先进自动化技术确保中线调水畅通

.绿色理念背景下电厂自动化控制系统研究

.大型自动化控制系统故障报警技术应用研究

.煤矿电气自动化控制系统优化设计

.配网自动化相关技术的研究

.中心城市大型配电自动化设计方案与应用

.自动化专业卓越工程师课程体系的改革与实践

.综合自动化变电站电压量传输新方式

.浅谈析电气自动化中的接地及保护

.办公自动化在飞行中的应用

.天津城市核心区配电自动化技术实施与进展

.配电自动化系统中配电终端配置数量规划

.倍福科技自动化技术助力高性能设备状态监测

.渠道自动化控制系统与运行设计探析

.自动化仓储系统优化方法的研究

.配网自动化建设与运行管理问题探微

.浅谈变电站综合自动化系统的`结构形式

.变电站综合自动化通信系统运行维护分析

.无功补偿技术在电气自动化中的应用

.基于PIE的高分遥感泥石流自动化变化检测方法研究

.电力自动化技术的新发展

.配电自动化试点工程技术特点及应用成效分析

.藁城新区水厂的自动化建设

.配电自动化若干问题的探讨

.工业自动化仪表故障分析及解决方法探析

.建筑电气自动化系统安装的施工技术探讨

.浅谈自动化仪表日常维护与故障解决

.浅谈电力自动化管理系统

.浅谈自动化控制系统及热工仪表的维护与管理

.电气自动化工程控制系统的现状及其发展趋势

.动力部一降压变电站综合自动化系统改造及应用

.新型智能配电自动化终端自描述功能的实现

.水电厂电气自动化控制设备的可靠性探讨

.国外配网自动化建设模式对我国配网建设的启示

.现场总线与工厂底层自动化及信息集成技术

.铝工业电气自动化的现状与发展趋势

有关自动化类论文题目

楼主大大要和你的文章内容适合哦

1. PLC控制花样喷泉.doc 2. S7-200PLC在数控车床控制系统中的应用3. PLC控制五层电梯设计 4. 超高压水射流机器人切割系统电气控制设计5. 基于PLC的恒压供水系统设计 6. 西门子PLC交通灯毕业设计7. 双恒压供水西门子PLC毕业设计 8. 世纪星组态 PLC控制自动配料系统毕业论文9. 三菱梯形图PLC控制四层电梯 10.三菱PLC五层电梯控制11.全自动洗衣机西门子PLC控制 12.欧姆龙PLC控制交通灯13.基于PLC电机故障诊断系统设计 14.双恒压无塔供水系统plc设计毕业论文15.工业用洗衣机的PLC控制 在配料生产线上的应用 毕业论文17.变频调速恒压供水系统 电梯控制毕业论文19.基于PLC电梯控制设计 20.基于PLC中断技术的集选电梯控制系统实现

楼主是什么歇学习阶段呢，你擅长什么呢？

电梯的PIC程序控制 这是我的毕业论文题目 咋俩同专业 或者 路口交通灯的PLC控制 这个就太简单了 还有啥 我给忘了、。。。

有关自动化创新的论文题目

机械专业粗略分为机械制造及自动化、机电一体化工程、工业工程、机电系统智能控制等四大类。那么机械专业的论文题目怎么选呢?下面我给大家带来2021机械机电类专业论文题目有哪些，希望能帮助到大家!

机电专业 毕业 论文题目

1、机电一体化与电子技术的发展研究

2、变频技术在锅炉机电一体化节能系统中应用

3、煤矿高效掘进技术现状与发展趋势研究

4、电气自动化在煤矿生产中的应用探讨

5、产品设计与腐蚀防护的程序与内容

6、机械制造中数控技术应用分析

7、智能制造中机电一体化技术的应用

8、水利水电工程的图形信息模型研究

9、矿山地面变电站智能化改造研究

10、浅析电气控制与PLC一体化教学体系的构建

11、中国机电产品出口面临的障碍及优化对策

12、我国真空包装机械未来的发展趋势

13、煤矿皮带运输变频器电气节能技术的分析

14、钢铁企业中机电一体化技术的应用和发展

15、我国机械设计制造及其自动化发展方向研究

16、机械设计制造及其自动化发展方向的研究

17、基于BIM技术的施工方案优化研究

18、电力自动化技术在电力工程中的应用

19、电气自动化技术在火力发电中的创新应用

20、农机机械设计优化方案探究

21、区域轨道交通档案信息化建设

22、环保过滤剂自动化包装系统设计

23、元动作装配单元的故障维修决策

24、关于机械设计制造及其自动化的设计原则与趋势分析

25、试析机电一体化中的接口问题

26、汽车安全技术的研究现状和展望

27、太阳能相变蓄热系统在温室加温中的应用

28、关于在机电领域自动控制技术应用的研究

29、浅析生物制药公司物流成本核算

30、锡矿高效采矿设备的故障排除与维护管理

31、铸钢用水玻璃型砂创新技术与装备

32、空客飞行模拟机引进关键环节与技术研究

33、汽车座椅保持架滚珠自动装配系统设计

34、液压挖掘机工作装置机液仿真研究

35、基于新常态视角下的辽宁高校毕业生就业工作对策研究

36、石油机电事故影响因素与技术管理要点略述

37、基于铝屏蔽的铁磁性构件缺陷脉冲涡流检测研究

38、数控加工中心的可靠性分析与增长研究

39、数控机床机械加工效率的改进 方法 研究

40、浅析熔铸设备与机电一体化

41、冶金电气自动化控制技术探析

42、中职机电专业理实一体化教学模式探究

43、高职机电一体化技术专业课程体系现状分析和改革策略

44、高速公路机电工程施工质量及控制策略研究

45、对现代汽车维修技术 措施 的若干研究

46、建筑工程机电一体化设备的安装技术及电动机调试技术分析

47、智能家居电话控制系统的设计

48、电力系统继电保护课程建设与改革

49、PLC技术在变电站电容器控制中的应用分析

50、机电一体化技术在地质勘探工程中的应用

机械类cad毕业论文题目

1、CAD技术在机械工艺设计中的应用研究

2、Auto CAD二次开发及在机械工程中的应用

3、基于特征的机械设计CAD系统研究

4、CAD在机械工程设计中的应用分析

5、机械制造中机械CAD与机械制图结合应用研究

6、浅谈CAD在机械制造业中起到的作用

7、智能CAD技术在机械制造中的应用

8、CAD/CAM技术在机械设计与制造中的应用研究

9、CAD制图技术在机械工程中的开发和应用

10、基于CAD/CAE的机械结构设计模式研究

11、基于机械制图与机械CAD应用环节协调分析

12、浅谈CAD技术在机械工程设计中的应用

13、三维CAD技术在机械设计中的应用

14、基于CAD的偏置曲柄滑块机构的设计与研究

15、应用CAD软件绘制机械零件图的创新方法

16、应用CAD图解法设计凸轮轮廓曲线的新方法

17、浅谈CAD外部参照在机械设计中的使用

18、五杆机构的CAD系统研究与开发

19、国内双圆弧齿轮CAD/CAE研究进展

20、连杆式少齿差减速机的CAD参数化设计

21、CAD实体模型直接分层软件设计

22、基于MBD的三维CAD模型信息标注研究

23、对提高CAD绘图速度的几点建议

24、Auto CAD在机械制图中的应用

25、机械传动系统方案设计CAD专家系统的研究

26、基于数值图谱法的连杆机构尺度综合CAD系统

27、浅谈Auto CAD在机械制图中的应用

28、基于CAD的液压传动技术综合性实验研究

29、圆柱凸轮CAD/CAM研究开发及在一次性卫生用品自动生产线中的应用

30、基于Creo的轴类零件CAD/CAPP集成系统开发

31、航空齿轮泵NX/CAD系统的界面实现

32、实现滚珠丝杠副AutoCAD/CAPP一体化

33、三维CAD技术在机械设计中的应用探讨

34、基于VB的弧面分度凸轮机构CAD系统设计

35、三维CAD技术对机械设计的影响管窥

36、液压系统原理图CAD开发研究

37、基于许用压力角要求的共轭凸轮计算机辅助设计系统开发

38、关于CAD技术在机械可靠性优化设计中的应用分析

39、弧面凸轮的CAD系统研究与开发

40、本体驱动的跨CAD平台开放式零件资源库构建

41、机械制图与CAD一体化探讨

42、论机械CAD技术及发展趋势

43、行星齿轮传动CAD系统开发

44、基于CAXA的盘类凸轮CAD/CAM应用

45、基于CAD技术的法兰26963工艺工装设计

46、鼓形齿联轴器参数化CAD系统开发

47、基于改进CAD技术的机械工艺设计探析

48、基于Pro/E的剪叉式液压升降台CAD系统的研究与开发

49、基于CAD/CAE集成的起重性能计算及方案优化

50、论CAD技术的发展及其对机械制图的影响

机床夹具类毕业论文题目

1、可重构车身底盘焊装夹具设计

2、随行夹具针对柔性自动加工线适应性技术

3、智能柔性可重构焊装随行夹具系统应用研究

4、组合夹具在零件加工中的应用

5、一种电机轴承卧式安装自动化生产设备

6、拨叉零件加工工艺浅析及其铣槽夹具设计

7、盾构机法兰密封圆环件圆柱面径向孔加工钻模设计

8、角度可调式线切割机床夹具设计及有限元分析

9、数控机床及工艺装备的创新

10、机床夹具制造中组合加工法的应用

11、拨叉零件加工工艺浅析及其铣槽夹具设计

12、中职机械专业 教育 中的机床夹具问题

13、快速判断夹具过定位的方法

14、夹具设计方案的分析与优化

15、机床夹具设计改进思路分析

16、机床夹具中定位与夹紧的研究

17、试论机械加工工艺装备设计研究杨兴旺

18、基于UG的机床夹具应用研究

19、机床夹具中定位与夹紧的研究

20、油泵轴加工自动生产线方案

21、浅谈机床夹具的发展趋势

22、浅析机械加工中工装夹具的定位设计

23、基于坐标系转换的工装夹具调装技术研究孔

24、零件加工中的机床夹具设计作用

25、机床夹具设计改进思路分析

26、专用机床夹具设计的方法与技巧

27、基于DVIA Composer D动画在机床夹具CAI中的应用研究

28、机床夹具的设计探讨

29、谈机械加工工艺装备设计

30、电永磁技术在金属加工中的应用

31、柔性组合夹具在汽车零部件制造中的应用研究

32、汽车扭杆力臂尾部平面铣削新型组合夹具

33、采矿装备制造中的先进焊接工装夹具应用研究

34、基于水泵机械制造工艺的设计探究

35、可调整夹持力的多功能夹具设计卜祥正

36、中小批量偏心凸轮的数控车削加工

37、光栅尺支架夹具设计的探讨

38、零件加工中的机床夹具设计作用

39、基于ANSYS的机床夹具的静动态特性分析

40、大直径圆周均布孔加工方法的研究

41、人机操作分析在底座生产线改进中的应用

42、液压阀体主阀孔车削成组夹具的设计与应用

43、法兰盘车床组合夹具设计

44、操纵杆支架Φ孔工艺及组合夹具设计

45、基于UG参数化设计的钻模设计

46、便携式高压隔离开关触头拆卸组合夹具的设计与研究

47、旋转式磁力片自动化装配系统及关键工位设计

48、机床夹具设计方法的应用

49、数控模具零件的铣夹具设计方法研究

50、一种小型叉形接头的精密加工技术

机械机电类专业论文题目有哪些相关 文章 ：

★ 机械类毕业设计论文题目

★ 机械类学术论文题目

★ 最新机械电子工程论文题目

★ 机电专业毕业论文范文

★ 机电专业技术论文(2)

★ 机械类科技论文范文(2)

★ 机电工程毕业论文范文

★ 机械电子工程方面论文

★ 机电相关毕业设计论文范文

电气工程中自动化技术的专业研究 关于电类专业毕业设计指导模式的研究浅谈电气工程及其自动化专业实践教学的创新模式 尽量写一个方向里的小点，不要把题目取得太大，太大不容易写好，以上仅供参考

机械制造与自动化论文

有关机械设计制造的发展及其应用论文