可以找清北医学翻译,这家收费不贵,价格也合适。
就目前人工智能的发展水平来看,机器降重还远远做不到“准确读取语句的意思,并将之用不同的词汇表述出来”我学姐推荐的北京译顶科技那边做的不错,你可以考虑一下。你可以加速去知道了解下
毕业设计不会做,抄也要讲究方法作为一个已经毕业了的大学生,在做毕业设计的过程中,无论是设计成果的研究还是毕业论文的撰写,不可回避的一个问题就是抄袭。作为一个过来人,我想说的是,做毕业设计难免会有抄袭的现象,但是一定要掌握方法,千万不要盲目的抄完了事,那样做是非常危险的。有的同学看都不看就抄到论文上去了,有的同学拿着别人做完的东西都不研究一下就参加答辩去了。我就听过一个活生生、血淋淋的例子——老师问:“你这段代码是什么意思?”答:“我不知道。”老师又问下一段代码,又不知道,老师问:“这是你做的吗?”答:“不是,老师给的。”其结果可想而知了。你们想想,那些东西都是往届毕业生做出来的,老师们能看不出来吗?掩耳盗铃,自欺欺人,大家都是成年人,我想不用多说了吧。大家在完成毕业设计的过程中肯定会遇到各种各样的现实性困难,成果做不出来了怎么办?论文写不出来了怎么办?外文文献不会翻译怎么办?其实这都好办,世界上再难的技术也是人做出来,没有成果就找个现成的东西;论文写不出来就多看几本书,多引用书里的内容;外文水平不高就用翻译软件。总之一句话,你有张良计,我有过墙梯,物竟天择,适者生存。文章转自 众赏文库 毕业设计论文,专业文档下载
最简单的事用金山词霸翻译
1. 写关于翻译技巧心得等。2.关于日本文化的研究,以及这些研究给翻译工作带来的便利和准确度上升等等。我觉得这个比较好写,资料有很多,然后用一些例文去证明你的观点就可以。3.写一些翻译误区的研究。最好去问问你的学长他们是怎么过的毕社,找一些做参考。或者直接和你导师讨论。
まずは紧张しないでください。わりと思ったより简単ですよ。质问は大抵あなたの论文に基づいたものです。ですから、自分の书いたものを自分なりに理解しなければなりませんね。ほかに、翻訳理论についてもいくつか质问されるかもしれません。とりあえず、落ち着いて考えて答えなさい。きっと大丈夫と思いますわ。
在google在线翻译中找,里面没有就找北京译顶科技,人工翻译反而更好
毕业论文外文翻译是在网上找到一篇与你论文主旨相关的英文文章,然后自己翻译过来,篇幅必须长一点,因为一般毕业设计都要有字数限制。
本科毕业设计(论文)外文翻译基本规范:
一、要求
1、与毕业论文分开单独成文。
2、两篇文献。
二、基本格式
1、文献应以英、美等国家公开发表的文献为主(Journals from English speaking countries)。
2、毕业论文翻译是相对独立的,其中应该包括题目、作者(可以不翻译)、译文的出处(杂志的名称)(5号宋体、写在文稿左上角)、关键词、摘要、前言、正文、总结等几个部分。
3、文献翻译的字体、字号、序号等应与毕业论文格式要求完全一致。
4、文中所有的图表、致谢及参考文献均可以略去,但在文献翻译的末页标注:图表、致谢及参考文献已略去(见原文)。(空一行,字体同正文)
5、原文中出现的专用名词及人名、地名、参考文献可不翻译,并同原文一样在正文中标明出处。
三、毕业论文(设计)外文翻译的内容要求
外文翻译内容必须与所选课题相关,外文原文不少于6000个印刷符号。译文末尾要用外文注明外文原文出处。
原文出处:期刊类文献书写方法:[序号]作者(不超过3人,多者用等或et al表示).题(篇)名[J].刊名(版本),出版年,卷次(期次):起止页次。
原文出处:图书类文献书写方法:[序号]作者.书名[M].版本.出版地:出版者,出版年.起止页次。
原文出处:论文集类文献书写方法:[序号]作者.篇名[A].编著者.论文集名[C]. 出版地:出版者,出版年.起止页次。
要求有外文原文复印件。
扩展资料:
文献翻译要求
1、翻译要注重专业、准确
文献翻译涵盖许许多多的学科,每一学科都有自己的专业术语。比如,从事专利文献翻译的译者必须对相关专业术语有着深入的了解和清楚的把握,这样才能用专业、准确、规范的语言翻译出来。
2、翻译要注重知识更新
文献翻译涉及到各种学科,这些学科的发展是与时俱进的。因此,译员也要与时俱进,随时掌握最新的知识,这样才能更好地胜任翻译任务。
3、翻译要注重本地化
无论是将国外的文献翻译进来,还是将国内的文献介绍出去,翻译时都必须注意语言的本地化,符合目标语言的习惯。
4、翻译要注重语言严谨、流畅
文献翻译一方面讲究语言的严谨科学,逻辑的连贯严密,另一方面它也注重文字尽可能的优美流畅。因此,这类翻译对译者的目标语言使用能力是一种挑战。
参考资料:百度百科-文献翻译
在某宝上面输入“毕业论文翻译神器”一下子就找到了。我用过,速度很快。当然好东西,也就不是免费的。不过,也不贵。也就一两块钱一页。我翻译了上万字,才花了10块钱。你可以去试试。这总比自己一句句翻块多了
不太建议直接抄袭,抄袭的文章查重的时候就过不了,不过你可以去试试找北京译顶科技,那边可以帮到你的
先说格式:两个封面,封面1用汉语(方便学校归档),封面2用法语。封面包含论文题目,名字,班级或学籍好,指导教师等。接下来是Remerciments(本科论文这部分也可以不写,但最好是有,会感觉比较专业)然后是Résumé(不宜太长,一页左右),包括下面几个内容:1.Sujetetpointimportant2.Méthode(即简单说明一下编写论文你所采取的方式手法)3.Présentationdechaquepartie(从哪几个方面来说明主题,论文的意义何在等)4.Conclusion紧接着Résumé,应该是motsclefs(不要多,三五个即可)然后是Sommaire(Tabledesmatières)即目录进入正文部分,一开始应该有个Introduction,包括:1.Remarquegénérale(即关于你所选的主题都已经有过哪些研究成果,文学方面的论文一定要写)2.Questionnement(针对这些已经有过的研究还哪些问题,可以是你不同意别人的观点,也可以是你认为可以扩展的,等等)3.Problématique+méthologie(扩展你的主题)4.Annonceduplan(尤其要指出你的立足点以及你这篇论文的重要性)Introduction完了之后,就是论文的主要部分了接着是Conclusion(1ou2pages)-unereprisedel'introduction,maisl'utilisationd'autreterme(其实也就是对Introduction的重述,但换一种表达方式)接下来是Notes,你的论文中一定有一些引用或者是需要说明的部分,在正文中加入批注(如①②③等)最后别忘了你的Bibliographie,你的参考书目。基本上就是这些东东了,我这个可能太理论化,其实你可以参考一下别人的论文,可能会更有体会。关于题目,本科生的话,我建议写文化方面的,资料比较多,论据也比较好找。比如中法之间的茶文化比较啊,酒文化比较啊之类的。当然如果有比较喜欢的法国作家,也可以分析他的作品什么的。或者选择语言文化方面的,比如说通过一些俗语或是成语的表达法,还有颜色词汇等的使用,说明文化差异对语言的影响等等,总之文化方面很多东西可以提出来写的啦。希望能对你有一点帮助。
如果明显是引用的资料,那就要标出;如果可以作为自己的想法,可以不标出。
毕业论文(学士的):mémoire毕业论文(博士的):thèse实习:stage我觉得楼上的翻译是英语,法语中的graduation是刻度的意思
你想累死我啊 下星期在发给你
下个金山快译2009就可以了,让她给你翻译
4 。结论 本文提出了一种参数调查缺损现象与理论分析和有限元制定的挤压过程是。为参数分析,五个重要的工艺参数进行了研究。从数值结果,已观察到,车轮速度并不影响分离的现象,而其他参数。摩擦系数和相对闪存差距直接相关的物质流ratethrough闪存差距和展览几乎相同的效果,增加了克制的缺陷比例 程度。另一方面,相对高度限制坝肩缺陷发生根据其增加而挤压比有利于增加。 此外,限制挤压比率建议对其他工艺参数,例如,该进程可以挤出产品的内部缺陷。
Punching die has been widely used in industrial production.In the traditional industrial production,the worker work very hard,and there are too much work,so the efficiency is low.With the development of the science and technology nowadays,the use of punching die in the industial production gain more attention, and be used in the industrial production more and more.Self-acting feed technology of punching die is also used in production, punching die could increase the efficience of production and could alleviate the work burden,so it has significant meaning in technologic progress and economic value.The article mainly discussed the classification,feature and the developmental direction of the pnnching technology. Elaborated the punching components formation principle, the basic dies structure and the rate process and the principle of design; and designed some conventional punching die:the die for big diameter three direction pipe which solved the problom of traditional machining,the drawing and punching compound die with float punch-matrix,the drawing and cutting compound dies with unaltered press,the compound die for the back bowl of the noise keeper,the design of the compound die which could produce two workpieces in one punching,the bending die for the ring shape part ,the bending die which used the gemel ,automate loading die for cutting, the drawing,punching and burring compound dies with sliding automated loading,the punching die for the long pipe with two row of hole,the drawing die for the square box shape workpiece and the burring die for the box shape workpiece.The punching dies that utilized the feature of the normal punch shaped the workpiece in the room temperature,and its efficiency and economic situation is excellent.The dies here discussed can be easily made,conveniently used, and safely operated.And it could be used as the reference in the large scale production of similar workpieces.CAD and CAM are widely applied in mould design and mould making. CAD allows you to draw a model on screen, then view it from every angle using 3-D animation and, finally, to test it by introducing various parameters into the digital simulation models(pressure, temperature, impact, etc.) CAM, on the other hand, allows you to control the manufacturing quality. The advantages of these computer technologies are legion: shorter design times(modifications can be made at the speed of the computer),lower cost, faster manufacturing, etc. This new approach also allows shorter production runs, and to make last-minute changes to the mould for a particular part. Finally, also, these new processes can be used to make complex parts.Computer-Aided Design(CAD)of MouldTraditionally, the creation of drawings of mould tools has been a time-consuming task that is not part of the creative process. Drawings are an organizational necessity rather than a desired part of the process.Computer-Aided Design(CAD) means using the computer and peripheral devices to simplify and enhance the design process .CAD systems offer an efficient means of design, and can be used to create inspection programs when used in conjunction with coordinate measuring machines and other inspection equipment.CAD data also can play a critical role in selecting process sequence.A CAD system consists of three basic components: hardware, software, users. The hardware components of a typical CAD system include a processor, a system display, a keyboard, a digitizer, and a plotter. The software component of a CAD system consists of the programs which allow it to perform design and drafting functions. The user is the tool designer who uses the hardware and software to perform the design process.Based on the 3-D data of the product, the core and cavity have to be designed first. Usually the designer begins with a preliminary part design, which means the work around the core and the cavity could change. Modern CAD systems can support this with calculating a split line for a defined draft direction, splitting the part in the core and cavity side and generating the run-off or shut-off surfaces. After the calculation of the optimal draft of the part, the position and direction of the cavity, slides and inserts have to be defined .Then in the conceptual stage, the positions and the geometry of the mould components---such as slides, ejection system, etc.----are roughly defined. With this information, the size and thickness of the plates can be defined and the corresponding standard mould can be chosen from the standard catalog. If no standard mould fits these needs, the standard mould that comes nearest to the requirements is chosen and changed accordingly---by adjusting the constraints and parameters so that any number of plates with any size can be used in the mould. Detailing the functional components and adding the standard components complete the mould(Fig.23.1).This all happens in 3-D. Moreover, the mould system provides functions for the checking, modifying and detailing of the part .Already in this early stage, drawings and bill of materials can be created automatically.Through the use of 3-D and the intelligence of the mould design system, typical 2-D mistakes---such as a collision between cooling and components/cavities or the wrong position of a hole---can be eliminated at the beginning. At any stage a bill of materials and drawings can be created---allowing the material to be ordered on time and always having an actual document to discuss with the customer or a bid for a mould base manufacturer.The use of a special 3-D mould design system can shorten development cycles, improve mould quality, enhance teamwork and free the designer from tedious routine work. The economical success, however, is highly dependent upon the organization of the workflow. The development cycles can be shortened only when organizational and personnel measures are taken. The part design, mould design, electric design and mould manufacturing departments have no consistently work together in a tight relationship.Computer-Aided Manufacturing(CAM)of MouldOne way to reduce the cost of manufacturing and reduce lead-time is by setting up a manufacturing system that uses equipment and personnel to their fullest potential. The foundation for this type of manufacturing system is the use of CAD data to help in making key process decisions that ultimately improve machining precision and reduce non-productive time. This is called as computer -aided manufacturing (CAM).The objective of CAM is to produce, if possible, sections of a mould without intermediate steps by initiating machining operations from the computer workstation.With a good CAM system , automation does not just occur within individual features. Automation of machining processes also occurs between all of the features that make up a part, resulting in tool-path optimization. As you create features ,the CAM system constructs a process plan for you .Operations are ordered based on a system analysis to reduce tool changes and the number of tools used.On the CAM side, the trend is toward newer technologies and processes such as milling to support the manufacturing of high-precision injection moulds with 3-D structures and high surface qualities. CAM software will continue to add to the depth and breadth of the machining intelligence inherent in the software until the CNC programming process becomes completely automatic. This is especially true for advanced multifunction machine tools that require a more flexible combination of machining operations. CAM software will continue to automate more and more of manufacturing's redundant work that can be handled faster and more accurately by computers , while retaining the control that machinists need.With the emphasis in the mould making industry today on producing moulds in the most efficient manner while still maintaining quality, moludmakers need to keep up with the latest software technologies-packages that will allow them to program and cut complex moulds quickly so that mould production time can be reduced. In a nutshell, the industry is moving toward improving the quality of data exchange between CAD and CAM as well as CAM to the CNC, and CAM software is becoming more "intelligent" as it relates to machining processes_resulting in reduction in both cycle time and overall machining time. Five-axis machining also is emerging as a "must-have" on the shop floor-especially when dealing with deep cavities.And with the introduction of electronic data processing(EDP)into the mould making industry, new opportunities have arisenin mould-making to shorten production time, improve cost efficiencies and higher quality.