Development and application of single chip microcomputer

Development and application of an underhood airflow simulation methodologyfor passenger carsJeroen VancoillieSupervisor(s):Sebastian Verhelst,Michel de Paepe,Roger Van WissenAbstract—Simulation has recently been introduced at Toyota Motor Europe to optimize the design of vehicle cooling systems. This abstract describes the developed methodology to solve the airflow through the engine compartment and predict the perfor-mance of the front end heat exchangers by means of CFD.The procedure to build a simulation model is discussed and the se-lection of submodels is motivated.Finally the model’s prediction performance is illustrated by an example result.Keywords—Vehicle cooling,underhood,heat exchanger,CFDI.I NTRODUCTIONV EHICLE cooling requirements are rising.Today’s new vehicles feature high horsepower engines and an underhood compartment crowded with technology to satisfy costumers’expectations regarding performance, safety,comfort and environmental impact.Moreover the shortened development times and high number of powertrain variants are placing additional stress on the designers of cooling systems.The airflow through the front end heat exchangers is critical for the cooling performance of a vehicle.Car manufacturers are taking this into consideration when designing a vehicle.Since many contradicting factors are defining the front end design,a clear understanding of the airflow behavior and its influence on the cooling performance is required.Many have resorted to compu-tationalfluid dynamics(CFD)to get this understanding. The aim of my thesis work was to confirm CFD as a valuable tool for cooling systems’design.In order to serve as a virtual sign-off,the simulation must be able to predict values for critical cooling performance parame-ters,such as engine coolant temperatures.II.S COPE OF THE WORKIn the course of this project we developed a time-and cost-efficient simulation methodology and applied it to a specific vehicle.The vehicle of interest was a Toy-ota Avensis2.2l Diesel with a6-speed automatic trans-mission.The cooling module contains a condenser,full face intercooler,radiator and two fans.A cooling loop for the automatic transmissionfluid(ATF)brings about additional complexity.It consists of an air-to-oil cooler and a little tubular water-to-oil cooler in the radiator out-let tank.III.M ETHODOLOGY AND MODELSFigure1summarizes the procedure to build and val-idate the underhood CFD model.The various steps are treated in more detailbelow.Fig.1.Procedure to build and validate the modelA.Fluid modelingWe selected the CFD software STAR-CCM+to per-form the analysis[1].This program uses thefinite-volume method to numerically solve the Navier-Stokes equations forfluid behavior.Since the Reynolds number forflow around a vehicle is in the range106-107turbulence must be accounted for.Because we are only interested in the influence of turbulence on the meanflow,the realizable k- model was used.A two-layer all y+wall treatment was used,which should provide acceptable near-wall modeling for wall cells in the log-layer,buffer layer and viscous sublayer. The wall treatment is considered accurate enough be-cause we saw theflow is guided more by pressure ef-fects than separation effects.The temperature dependence offluid properties is considered in the model.We found that neglecting this can lead to inaccuracies of more than10%on the pre-dicted airflow rates.putational domain and complex geometryWe combined vehicle CAD data to form an accurate representation of the underhood geometry.Geometri-cal assumptions were minimized by including the entire vehicle exterior in the model.To have a fast process,wrapping technology was used to produce a single,airtight,non-intersecting surfacerepresentation of the vehicle.This is a requisite for the automatic volume mesh creation.Because of limited computational resources we had tofind a trade-off be-tween mesh detail and calculation turnaround time.We used grid refinements only where they are needed the most:at the grill,front end and cooling module.Spe-cial care was taken of low quality grid cells to avoid loss of solution robustness.C.Heat exchanger modelBecause earlier work showed that the heat exchanger and fan representation are critical to the model accuracy [2],we tested the performance of these submodels sep-arately.The heat exchanger core is modeled as a rectangu-lar domain with specified correlations for heat transfer and pressure drop in function of localflow velocity.We calculated these correlations from heat exchanger per-formance data.The model’s accuracy was confirmed by recreating the heat exchanger performance measurements on a vir-tual test rig.The predicted pressure drop and heat rejec-tion were within2%of the measured values.D.Fan modelTo keep the computational cost low,we selected the body force model to represent the fan.The blade ge-ometry is not imported physically,but its contributions to momentum(pressure rise and swirl)are handled with source terms in the Navier-Stokes equations.Earlier work illustrated that this model performs quite well at high fanflow rates[3].The model uses a user-supplied fan curve to calculate the fan operating point and is very dependent on the quality of this fan curve. From simulation results we saw that the fan is actu-ally operating at lowflow rates,where the model per-forms poorly.Also it is currently not clear how the fan curves were obtained.We suspect that the fan model might not be so accurate.In the future more compli-cated fan models might be considered.E.Boundary and operating conditionsAs reported in earlier work[2],we saw that the pre-dicted coolant temperatures are very sensitive to the en-gine heat release.The same is true for heat released to the transmissionfluid.So to have good predictions,ac-curate values are needed for these boundary conditions. We found that in order to get these values,a sound un-derstanding of the engine and torque converter operat-ing point is required.Once these operating points werefixed,we used a 1D simulation model of the coolant loop to predict the coolantflow rate and the engine heat release.For the charge air we used engine maps tofind the theflowrate and intercooler inlet temperature.The heat release to the transmissionfluid was calculated from the torque converter and gearing efficiency.No accurate estimations could be obtained for the transmissionfluidflow rate and the distribution of heat between the air-to-oil and water-to-oil cooler.We con-cluded that the complex hydraulics of the transmission fluid should be considered in a separate1D model.F.SolverTheflow equations were solved in steady state formu-lation.We selected second order discretization to ob-tain good quality results on the complex grid.The solu-tion was considered converged once the scaled residuals had dropped by3to4orders of magnitude and physical values,like coolant temperatures,were stabilized.The full model took1000-2000iterations to converge,which takes about1.5days on an8processor workstation. G.Turnaround timeWith the current methodology an underhood simu-lation model can be built from scratch in about2to3 weeks.Potentially this time can be reduced by automa-tion of the geometry handling and model setup.IV.R ESULTSFigure2shows an example of results obtained with thefinal model.Expectedflow phenomena,like leak-ageflow past the cooling module and recirculation of fan air,are well predicted.The absolute temperature values for coolant and transmissionfluid are in the good range.The remaining errors are mainly caused by in-accurate boundary conditions.The model’s accuracy will be confirmed by wind tunnel measurements,where the boundary conditions can be controlled and are wellknown.Fig.2.Cross-section of the underhood velocityfield:side viewV.C ONCLUSIONWe can conclude that CFD can be used to under-stand theflow phenomena affecting the cooling mod-ule.STAR-CCM+offers sufficient tools to handle the complex underhood geometry and model the heat ex-changer and fan operation.The developed model is able to predict realistic values for the cooling performance parameters and represents the anticipatedflow phenom-ena well.Wind tunnel measurements will be done to confirm the accuracy.Although there is still room for improvement,both on accuracy and turnaround time, the model is already used at Toyota to improve the front end design.R EFERENCES[1]CD-Adapco,STAR-CCM+Version4.02User’s Manual,2009[2] A.Jerhamre&A.J¨o nson,Development and validation of coolanttemperature and cooling airflow CFD simulations at Volvo Cars, SAE-2004-01-0051,2004[3]T.Oshima,ita&M.Yamamoto,Development of predic-tion method for performance of cooling airflow in engine com-partment using computationalfluid dynamics,Mitsubishi Motors Technical Review,volume13,p.42-51,2001。

单片机的发展与应用摘要：本文阐述了单片机基本组成以及一般原理。

通过查阅相关资料认真总结了单片机的原理、应用、发展以及影响等方面的知识，较为详细地介绍当前单片机的应用领域以及发展历程、发展前景。

主要内容包括：单片机的基本原理、硬件结构、具体的应用以及发展的历史与趋势的介绍。

本文主要目的是想让大家对单片机有一个更为深入、更为全面的了解。

以期，在单片机发展迅速、应用领域不断扩大的当今社会能有一个更好的发展。

通过对本课题的研究发现，近年来。

单片机在国内的发展速度很快，应用领域也在不断扩大。

可见，单片机在国内的发展前景极为广阔。

关键词：单片机；芯片；发展；应用Development and application of single-chip Abstract: The Intel MCS-51 series single-chip model, the basic components of single-chip, as well as general principles. Access to relevant information through carefully summed up the principle of single-chip, application, development and impact of knowledge, a more detailed description of the current single-chip applications as well as the development process, development prospects. The main contents include: the basic principles of single-chip, hardware structure, and specific applications and the development trend of the history and introduction. The main purpose of this paper is to make everyone have a more in-depth single-chip, a more comprehensive understanding. With a view to, the rapid development in the single-chip applications expanding today's society to have a better development. The subject of this study found that in recent years. Single-chip in the development of the domestic fast, applications are also expanding. This shows that single-chip prospects in the country are extremely broad.Keyword: single-chip; chip; development; application;目录1.引言................................................. 错误!未指定书签。

毕业设计（论文）外文参考资料及译文译文题目： development and application of combinedmachine tool组合机床的发展与应用学生姓名：王斑学号： 1021108014专业： M10机械设计制造及其自动化所在学院：机电工程学院指导教师：赵海霞职称：教师2014年 2 月 25 日Development and application of combined machine tool The aggregate machine-tool is take the general part as a foundation, matches by presses the work piece specific shape and the processing technological design special-purpose part and the jig, the composition semiautomatic or the automatic special purpose machine. The aggregate machine-tool selects the method which generally multiple spindle, the multi-knives, the multi-working procedures, many or the multi-locations simultaneously process, production efficiency ratio general engine bed high several times to several dozens times. Because the general part already the standardization and the seriation, might according to need to dispose nimbly, could reduce the design and the manufacturing cycle. The multi-axle-boxes are aggregate machine-tool's core parts. It selects the common parts, carries on the design according to the special-purpose request, in the aggregate machine-tool design's process, is one of work load big parts. It is acts according to the work piece processing hole quantity which and the position the working procedure chart and the processing schematic drawing determined, the cutting specifications and the main axle type design transmission various main axles movement power unit. Its power from the general power box, installs together with the power box in to feed sliding table, may complete drills, twists and so on working processes. To meet the combination of CNC machine tools of development, it is a component of the NC machine tool NC module. Portfolio machine is modular combination of CNC machine tools brought about by the inevitable result is the combination of CNC machine tools necessary foundation, NC module so greatly enriched the portfolio of generic pieces of machine tools, it will cause combination of General Machine Type of a fundamental change. NC module, according to their coordinates NC (axis) of mainly single coordinates, dual coordinate and coordinate. Its spindle number, single and multi-axis module, there are single and multi-axis composite processing module.NC module development, there are mainly two kinds of ways: First, the existing combination of machine tools should be relatively common items, the NC General of the design. At present there is also domestic NC is developing one-dimensional slider, NC two-dimensional (Cross) Waterloo Taiwan, the NC rotary table, all this is the way the NC is based on the characteristics of the development of NC The unique combination of machine tool parts, such as automatic replacement of multi-axis spindle box, the NCrotary knife, NC for the manipulator, NC for me, such as mechanical hand. The past 10 years, machine tools and automatic line group in the highly efficient, high productivity, flexibility and the use of parallel (synchronous) works develop more reasonable and more savings in the programme has made a lot of progress. In particular the automobile industry, in order to improve the performance of motor vehicles, precision machining of components made a number of new demands, so the machine performance requirements are also higher.In recent years, with numerical control technology, electronics technology, computer technology, such as the development of machine tools combination of mechanical structure and control system has also undergone a tremendous change. With the combination of machine tools of development: 1. NC. A combination of CNC machine tools, not only a complete change from the previous relay circuit composed of a combination of machine tool control system, and the head. Also the mechanical structure and composition of machine parts universal standards has or is undergoing an enormous change。

本科毕业设计基于单片机的空调遥控器摘要随着社会的发展，科技的进步以及人们生活水平的逐步提高，各种方便于生活的遥控系统开始进入了人们的生活。

电器在家庭中已经十分普及，与此同时，和电器相伴的空调遥控器的品种和产量不断提高。

传统的遥控器采用专用的遥控编码及解码集成电路，这种方式虽然制作简单容易，但由于功能键数及功能受到特定的限制，只实用于某一专用电器产品的应用，应用范围受到限制。

而采用单片机进行遥控系统的应用设计，具有编程灵活多样，操作码个数可随便设定等优点。

论文首先对遥控器的几个方案进行了论证，最终确定了一可行性方案，并对此方案进行了可行性分析之后提出了电器遥控器的硬件和软件设计方案。

在硬件设计方案中，首先详细论述了遥控器的基本原理并用实例进行了说明。

然后，对电器遥控器常用硬件设备原理和使用进行了讨论，并对设计中使用的单片机做了必要说明。

在软件设计方案中，论文对软件流程做了详细的解释并阐述了单片机软件设计的一般方法。

最后，论文对电器遥控器设计的硬、软件调试做了简单介绍。

关键字：遥控器电器遥控单片机Air Conditioner Remote Controller Based On Single Chip MicrocomputerFan Geqiang(College of Science, South China Agricultural University, Guangzhou 510642, China) Abstract：With the development of society, the progress of science and technology and the improvement of people's living standards, remote control systems to facilitate life begin to enter people's life. Electrical appliances have become very popular, in the family at the same time, and the air conditioning remote control electric appliance with variety and yield improvement.The traditional remote controller adopt special remote control coding and decoding integrated circuit, while this preparation is simple and easy, but because the function keys and function subject to certain limitations, application is applicable only to a special electrical products, limited application range. Design and application of single-chip control system with programmable, flexible operation, code can be arbitrarily set number etc.Firstly, several schemes for the remote control has been demonstrated, ultimately determine a feasible scheme, and this scheme for the feasibility of proposed electric appliance remote controller hardware and software design scheme. In hardware design, this paper firstly discusses the basic principle of the remote control and illustrates it with examples. Then, on a remote control electric appliance equipment commonly used hardware principle and application are discussed, and the design used in single-chip to do the necessary notes. In software design, the software process to do a detailed explanation and expounds the general method of MCU software design. Finally, the article on the remote controller design hardware, software debugging is introduced briefly.Keyword: remote control electric remote control single-chip目录1 引言 (1)2 方案比较 (1)2.1 方案一：多功能红外遥控器 (1)2.2 方案二：红外线电器遥控器 (2)2.3 方案三：空调遥控器 (2)2.4 方案比较 (3)3 空调遥控器硬件设计 (4)3.1 单片机选型 (4)3.2 红外发射电路设计 (4)3.2.1 红外遥控基本原理 (4)3.2.2 红外发射电路 (8)3.3 LCD驱动电路设计 (9)3.3.1 LCD基本原理 (9)3.3.2 LCD驱动电路（串列传输） (10)3.4 键盘、摇杆扫描电路设计 (11)3.4.1 键盘、摇杆基本原理 (11)3.4.2 键盘、摇杆扫描电路 (13)3.5 空调遥控器硬件电路图 (13)4 调试 (14)4.1 硬件调试 (14)4.2 软件调试 (15)4.3 故障诊断及排除 (15)5 总结 (15)致谢............................................................................................................... 错误!未定义书签。

流水灯毕业设计论文【篇一：毕业论文(设计)流水灯】毕业论文(设计)课题名称：基于mcs-51流水灯设计作者：周治雄学号： 1105050105 系别：信息工程系专业：制冷与空调技术班级：应用电子一班指导教师：汤泽容专业技术职务：2014 年 6 月重庆.涪陵摘要：当今时代是一个新技术层出不穷的时代，在电子领域尤其是自动化智能控制领域，传统的分立元件或数字逻辑电路构成的控制系统，正以前所未见的速度被单片机智能控制系统所取代。

单片机具有体积小、功能强、成本低、应用面广等优点，可以说，智能控制与自动控制的核心就是单片机。

关键词：led 单片机控制系统流水灯目录1 设计概述 (4)1.1 设计任务 (4)1.2 设备器材 (4)2 硬件设计方案 (4)2.1 设计思想 (4)2.2 硬件选择………………………………………………………………5 2.3at89c51单片机介绍..................................................................5 2.4 硬件逻辑图.....................................................................8 2.5 设计连线 (9)2.6 仿真电路图 (9)3 软件设计方案 (9)3.1 软件设计思想…………………………………………………………………9 3.2 软件设计思想………………………………………………………………10 3.3 程序流程图 (12)4 调试及运行结果……………………………………………135 设计心得与体会...................................................13 参考资料 (14)1 设计概述1.1 设计任务设计内容：利用汇编语言（或c语言），实现8个单色led灯的左、右循环显示，并实现循环的速度可调。

西安航空职业技术学院毕业设计（论文）论文题目：题目：电子密码锁防盗门所属系部：属系部：电子工程系指导教师：指导教师：职称：学生姓名：学生姓名：学号: 专业：电工西安航空职业技术学院制西安航空职业技术学院毕业设计（论文）毕业设计（论文）任务书题目：题目：电子密码锁防盗门任务与要求：时间：所属系部：所属系部：学生姓名：学生姓名：专业：专业：年月日至电工系年月日共周学号：电工指导单位或教研室：指导单位或教研室：指导教师：指导教师：职称：西安航空职业技术学院制2 摘要电子技术的迅速发展，特别是大规模集成电路的出现，给人类生活带来了根本性的改变。

尤其是单片机技术的应用产品已经走进了千家万户。

作为单片机技术应用之一的数字密码锁，在日常生活、工业场合甚至军事领域都有应用。

本文对目前楼宇门禁装置应用现状进行了分析,结合应用广泛的串行通信技术设计并实现了一个以AT89S52为核心的数字密码锁。

阐述了系统的结构、组成及软硬件设计，并介绍了系统的功能。

本系统具有自动报警、日历显示、掉电密码保护、权限管理、实时监控等功能，并可查询监控记录。

系统基于RS-232通信，监控主机和密码锁之间采用自定义协议进行串行通信。

监控软件采用Visual Basic 6.0实现。

实践结果表明该数字密码锁系统结构简单、性能稳定、智能化程度较高, 监控软件具有友好的人机界面和较好的实时性，系统实用性较强。

关键词: 关键词单片机，数字密码锁，实时监控，串行通信 3 Abstract Along with the electronic technology rapid development, appears of the large scale integrated circuit specially, these have made a big change on people’s living. Products including the technology application of the single chip microprocessor sets already entered every family. As one application of the single chip microprocessor technology, the digital combination lock has been applied in the daily life, the industry situation and military field. This article analyzes the current status of the application of Building Access Control Devices. The author designs a digital combination lock with the core of AT89S52 by combining the Serial Communication Technology. The article states structure, composition, the design of software and hardware, the function of the system. The system has such functions: Auto-alarm, Calendar Demonstration, Power Failure Password Protection, Rights Management, Real-time Monitoring and etc. It can also query the data that was recorded. The system is based on RS-232, and the communication between the host-computer and slave digital combination lock by adopting the self-define protocol. The monitor software is realized by Visual Basic 6.0. The result shows that this system has a simple structure, stable performance and higher degree of intelligence. The monitor software has a friendly User Interface, and the system is very practical. KEY WORDS: single chip microprocessor, digital combination lock, real-time monitoring, serial communication 目录第1章绪论......................................... 1 1.1 本课题研究的背景和意义.......................................................................................... 1 1.2 楼宇门禁系统的概述.................................................................................................. 1 1.3 本次设计的任务.......................................................................................................... 2 1.4 设计思想及系统方案选择.......................................................................................... 2 第 2 章基于单片机的数字密码锁的硬件设计....................... 4 2.1 MCU 的选择.............................................................................................................. 4 2.1.1 简单介绍AT89S52 ............................................................................................ 4 2.1.2 AT89S52 的串口通信......................................................................................... 7 2.1.3 晶振特性............................................................................................................ 8 2.2 输入通道设计.............................................................................................................. 9 2.2.1 键盘识别方法.................................................................................................... 9 2.2.2 消除键的抖动.................................................................................................. 11 2.2.3 键盘的选择...................................................................................................... 12 2.2.4 按键的设置...................................................................................................... 12 2.3 显示模块的设计........................................................................................................ 13 2.4 密码锁动作模块设计................................................................................................ 14 2.5 报警模块设计............................................................................................................ 15 2.6 通信模块设计............................................................................................................ 16 2.6.1 2.6.2 2.7.1 2.7.2 2.7.3 RS-232 简介................................................................................................... 18 MAX232 电路设计........................................................................................ 19 DS1302 简介................................................................................................. 21 DS1302 电路原理图...................................................................................... 22 DS1302 调试中的问题................................................................................. 22 2.7 时钟功能设计............................................................................................................ 21 2.8 供电电源模块设计.................................................................................................... 23 2.9 掉电保护设计............................................................................................................ 24 第 3 章基于单片机的数字密码锁的软件设计...................... 27 3.1 上位机监控软件设计................................................................................................ 27 3.1.1 VB 中的MSComm 通信控件....................................................................... 27 -1- 3.1.2 小区密码锁管理系统的设计.......................................................................... 29 3.2 下位机程序设计........................................................................................................ 30 3.2.1 软件设计的原则.............................................................................................. 30 3.2.3 程序流程图...................................................................................................... 30 第 4 章基于单片机的数字密码锁的功能......................... 34 第5章结论........................................ 40 致谢........................................................................................................................................ 41 参考文献.................................................................................................................................. 42 论文小结.................................................................................................................................. 43 附录（一）：硬件实物照片.................................................................................................. 45 附录（二）：电路原理图...................................................................................................... 46 -2- 第1章绪论1.1 本课题研究的背景和意义社会治安仍是当今社会面临的一个重大问题，如何应用高科技手段提高安全防范措施, 更有效地阻止犯罪行为的发生是科技工作者义不容辞的责任。

单片机的外文文献及中文翻译一、外文文献Title: The Application and Development of SingleChip Microcontrollers in Modern ElectronicsSinglechip microcontrollers have become an indispensable part of modern electronic systems They are small, yet powerful integrated circuits that combine a microprocessor core, memory, and input/output peripherals on a single chip These devices offer significant advantages in terms of cost, size, and power consumption, making them ideal for a wide range of applicationsThe history of singlechip microcontrollers can be traced back to the 1970s when the first microcontrollers were developed Since then, they have undergone significant advancements in technology and performance Today, singlechip microcontrollers are available in a wide variety of architectures and capabilities, ranging from simple 8-bit devices to complex 32-bit and 64-bit systemsOne of the key features of singlechip microcontrollers is their programmability They can be programmed using various languages such as C, Assembly, and Python This flexibility allows developers to customize the functionality of the microcontroller to meet the specific requirements of their applications For example, in embedded systems for automotive, industrial control, and consumer electronics, singlechip microcontrollers can be programmed to control sensors, actuators, and communication interfacesAnother important aspect of singlechip microcontrollers is their low power consumption This is crucial in batterypowered devices and portable electronics where energy efficiency is of paramount importance Modern singlechip microcontrollers incorporate advanced power management techniques to minimize power consumption while maintaining optimal performanceIn addition to their use in traditional electronics, singlechip microcontrollers are also playing a significant role in the emerging fields of the Internet of Things （IoT) and wearable technology In IoT applications, they can be used to collect and process data from various sensors and communicate it wirelessly to a central server Wearable devices such as smartwatches and fitness trackers rely on singlechip microcontrollers to monitor vital signs and perform other functionsHowever, the design and development of systems using singlechip microcontrollers also present certain challenges Issues such as realtime performance, memory management, and software reliability need to be carefully addressed to ensure the successful implementation of the applications Moreover, the rapid evolution of technology requires developers to constantly update their knowledge and skills to keep up with the latest advancements in singlechip microcontroller technologyIn conclusion, singlechip microcontrollers have revolutionized the field of electronics and continue to play a vital role in driving technological innovation Their versatility, low cost, and small form factor make them an attractive choice for a wide range of applications, and their importance is expected to grow further in the years to come二、中文翻译标题：单片机在现代电子领域的应用与发展单片机已成为现代电子系统中不可或缺的一部分。

中国单片机公共实验室英语Chinese Single-chip Microcontroller Public LaboratoryThe Chinese Single-chip Microcontroller Public Laboratory aims to provide a platform for individuals and organizations to conduct experiments and research on single-chip microcontrollers in China. The laboratory offers resources such as hardware equipment, software tools, and guidance from experienced professionals to support users in their projects.The objectives of the laboratory are:1. Promote the development and application of single-chip microcontrollers in China.2. Foster collaboration and knowledge-sharing among researchers and enthusiasts.3. Support innovation and entrepreneurship in the field of single-chip microcontrollers.4. Train and cultivate talents in the single-chip microcontroller industry.The laboratory offers access to various single-chip microcontroller development boards, such as Arduino, Raspberry Pi, and STM32, as well as other essential components and tools. Users can utilize these resources to design and test their projects, whether it be robotics, home automation, or electronic applications.In addition to hardware resources, the laboratory provides software tools and libraries for programming single-chip microcontrollers. Users can choose from different programming languages,including C/C++, Python, and Lua, to develop their applications. The laboratory also organizes workshops and training sessions to help users understand the fundamentals of single-chip microcontrollers and enhance their programming skills.To ensure the quality and safety of experiments conducted in the laboratory, there are guidelines and regulations that users must abide by. These include maintaining cleanliness and organization within the workspace, properly handling and disposing of materials, and respecting the intellectual property rights of others.By establishing the Chinese Single-chip Microcontroller Public Laboratory, we aim to foster a vibrant community of single-chip microcontroller enthusiasts and promote the development of innovative applications in China.。

As a high school student with a keen interest in technology and innovation, Ive always been fascinated by the world of microelectronics. This field, which deals with the design, development, and application of very small electronic components, is at the heart of modern technological advancements. My journey into the realm of microelectronics began with a simple curiosity about how everyday gadgets work, and it has evolved into a passion for understanding and contributing to this dynamic field.My first encounter with microelectronics was during a school project where we were tasked with building a simple circuit. It was a rudimentary project, but it sparked my interest in how these tiny components could be manipulated to perform complex tasks. I remember the excitement I felt when the circuit I had assembled lit up an LED for the first time. It was a small victory, but it ignited a desire to delve deeper into the subject.To further my understanding, I began to explore the world of microelectronic devices beyond the classroom. I read books, watched online tutorials, and even attended a few workshops. The more I learned, the more I realized the vast potential of microelectronics in shaping our future. From smartphones to satellites, from medical devices to the Internet of Things IoT, microelectronics is the backbone of modern technology.One of the most intriguing aspects of microelectronics for me is the constant innovation and the push towards miniaturization. The development of integrated circuits ICs has revolutionized the way we design and manufacture electronic devices. The ability to place millions oftransistors on a single chip is a testament to the incredible progress made in this field. I find it fascinating to think about how these tiny components can be so powerful and versatile.My interest in microelectronics led me to participate in a school science fair where I showcased a project on solarpowered microelectronic devices.I designed a small solar panel that could charge a battery and power a microcontroller, which in turn controlled a series of LEDs. The project was a success, earning me a silver medal and the admiration of my peers and teachers. But more importantly, it solidified my resolve to pursue a career in microelectronics.As I progressed through high school, I took advanced courses in physics and mathematics, which provided me with a strong foundation for understanding the principles of microelectronics. I also joined a robotics club where I had the opportunity to work with microcontrollers and sensors, applying my knowledge of microelectronics in a practical setting.One of the most memorable experiences I had was during a summer internship at a local tech company. I was fortunate enough to work alongside experienced engineers who were developing microelectronic components for use in aerospace applications. It was an incredible learning experience, and it gave me a glimpse into the professional world of microelectronics.Looking to the future, I am eager to pursue higher education in the field of microelectronics. I believe that with the right education and experience, Ican contribute to the ongoing advancements in this field. I am particularly interested in the development of energyefficient microelectronic devices, which could have a significant impact on reducing our carbon footprint and promoting sustainable development.In conclusion, my journey into the world of microelectronics has been both enlightening and inspiring. From my first simple circuit project to my experiences in the robotics club and my internship, I have gained a deep appreciation for the potential of microelectronics to shape our world. As I continue to learn and grow, I am excited about the opportunities that lie ahead and the role I can play in advancing this fascinating field.。

Single-chip1 The definition of a single-chipSingle-chip is an integrated on a single chip a complete computer system. Even though most of his features in a small chip, but it has a need to complete the majority of computer components: CPU, memory, internal and external bus system, most will have the Core. At the same time, such as integrated communication interfaces, timers, real-time clock and other peripheral equipment. And now the most powerful single-chip microcomputer system can even voice, image, networking, input and output complex system integration on a single chip.Also known as single-chip MCU (Microcontroller), because it was first used in the field of industrial control. Only by the single-chip CPU chip developed from the dedicated processor. The design concept is the first by a large number of peripherals and CPU in a single chip, the computer system so that smaller, more easily integrated into the complex and demanding on the volume control devices. INTEL the Z80 is one of the first design in accordance with the idea of the processor, From then on, the MCU and the development of a dedicated processor parted ways.Early single-chip 8-bit or all of the four. One of the most successful is INTEL's 8031, because the performance of a simple and reliable access to a lot of good praise. Since then in 8031 to develop a single-chip microcomputer system MCS51 series. Based on single-chip microcomputer system of the system is still widely used until now. As the field of industrial control requirements increase in the beginning of a 16-bit single-chip, but not ideal because the price has not been very widely used. After the 90's with the big consumer electronics product development, single-chip technology is a huge improvement. INTEL i960 Series with subsequent ARM in particular, a broad range of applications, quickly replaced by 32-bit single-chip 16-bit single-chip high-end status, and enter the mainstream market. Traditional 8-bit single-chip performance has been the rapid increase in processing power compared to the 80's to raise a few hundred times. At present, the high-end 32-bit single-chip frequency over 300MHz, the performance of the mid-90's close on the heels of a special processor, while the ordinary price of the model dropped to one U.S. dollars, the most high-end models, only 10 U.S. dollars. Contemporary single-chip microcomputer system is no longer only the bare-metal environment in the development and use of a large number of dedicated embedded operating system is widely used in the full range of single-chip microcomputer. In PDAs and cell phones as the core processing of high-end single-chip or even a dedicated direct access to Windows and Linux operating systems.More than a dedicated single-chip processor suitable for embedded systems, so it was up to the application. In fact the number of single-chip is the world's largest computer. Modern human life used in almost every piece of electronic and mechanical products will have a single-chip integration. Phone, telephone, calculator, home appliances, electronic toys, handheld computers and computer accessories suchas a mouse in the Department are equipped with 1-2 single chip. And personal computers also have a large number of single-chip microcomputer in the workplace. Vehicles equipped with more than 40 Department of the general single-chip, complex industrial control systems and even single-chip may have hundreds of work at the same time! SCM is not only far exceeds the number of PC and other integrated computing, even more than the number of human beings.2 single-chip introducedSingle-chip, also known as single-chip microcontroller, it is not the completion of a logic function of the chip, but a computer system integrated into a chip. Speaking in general terms: a single chip has become a computer. Its small size, light weight, cheap, for the learning, application and development of facilities provided. At the same time, learning to use the principle of single-chip computer to understand and structure the best choice.Single-chip and computer use is also similar to the module, such as CPU, memory, parallel bus, as well as the role and the same hard disk memory, is it different from the performance of these components are relatively weak in our home computer a lot, but the price is low, there is generally no more than 10 yuan ...... can use it to make some control for a class of electrical work is not very complex is sufficient. We are using automatic drum washing machines, smoke hood, VCD and so on inside the home appliances can see it's shadow! ...... It is mainly as part of the core components of the control.It is an online real-time control computer, control-line is at the scene, we need to have a stronger anti-interference ability, low cost, and this is off-line computer (such as home PC) The main difference.By single-chip process, and can be amended. Through different procedures to achieve different functions, in particular the special unique features, this is the need to charge other devices can do a great effort, some of it is also difficult to make great efforts to do so. A function is not very complicated if the United States the development of the 50's series of 74 or 60 during the CD4000 series to get these pure hardware, the circuit must be a big PCB board! However, if the United States if the successful 70's series of single-chip market, the result will be different! Simply because the adoption of single-chip preparation process you can achieve high intelligence, high efficiency and high reliability!Because of the cost of single-chip is sensitive, so the dominant software or the lowest level assembly language, which is in addition to the lowest level for more than binary machine code of the language, since such a low-level so why should we use? Many of the senior's language has reached a level of visual programming Why is it not in use? The reason is simple, that is, single-chip computer as there is no home of CPU, also not as hard as the mass storage device. A visualization of small high-level language program, even if there is only one button which will reach the size of dozens of K! For the home PC's hard drive is nothing, but in terms of the single-chip microcomputer is unacceptable. Single-chip in the utilization of hardware resourceshave to do very high, so the compilation of the original while still in heavy use. The same token, if the computer giant's operating system and applications run up to get the home PC, home PC can not afford to sustain the same.It can be said that the twentieth century across the three "power" of the times, that is, the electrical era, the electronic age and has now entered the computer age. However, such a computer, usually refers to a personal computer, or PC. It consists of the host, keyboards, displays and other components. There is also a type of computer, not how most people are familiar with. This computer is smart to give a variety of mechanical single-chip (also known as micro-controller). As the name suggests, these computer systems use only the minimum of an integrated circuit to make a simple calculation and control. Because of its small size, are usually charged with possession of machine in the "belly" in. It in the device, like the human mind plays a role, it is wrong, the entire device was paralyzed. Now, this single chip has a very wide field of use, such as smart meters, real-time industrial control, communications equipment, navigation systems, and household appliances. Once a variety of products with the use of the single-chip, will be able to play so that the effectiveness of product upgrading, product names often adjective before the word - "intelligent," such as washing machines and so intelligent. At present, some technical personnel of factories or other amateur electronics developers from engaging in certain products, not the circuit is too complex, that is functional and easy to be too simple imitation. The reason may be the product not on the cards or the use of single-chip programmable logic device on the other.3 single-chip historySingle-chip 70 was born in the late 20th century, experienced a SCM, MCU, SoC three stages.Single-chip micro-computer 1.SCM that (Single Chip Microcomputer) stage, is mainly a single form to find the best of the best embedded systems architecture. "Innovation model" to be successful, lay the SCM with the general-purpose computers, a completely different path of development. In embedded systems to create an independent development path, Intel Corporation credit.That is, 2.MCU microcontroller (Micro Controller Unit) stage, the main direction of technology development: expanding to meet the embedded applications, the target system requirements for the various peripheral circuits and interface circuits, to highlight the target of intelligent control. It covers all areas related with the object system, therefore, the development of MCU inevitably fall on the heavy electrical, electronics manufacturers. From this point of view, Intel's development gradually MCU has its objective factors. MCU in the development, the most famous manufacturers when the number of Philips Corporation.Philips in embedded applications for its enormous advantages, the MCS-51 from the rapid development of single-chip micro-computer to the microcontroller. Therefore, when we look back at the path of development of embedded systems, Intel and Philips do not forget the historical merits.3. Single-chip is an independent embedded systems development, to the MCU an important factor in the development stage, is seeking applications to maximize the on-chip solution; Therefore, the development of dedicated single-chip SoC formed a natural trend. With the micro-electronics technology, IC design, EDA tools development, based on the single-chip SoC design application systems will have greater development. Therefore, the understanding of single-chip micro-computer from a single, monolithic single-chip microcontroller extends to applications.4 single-chip applicationsAt present, single-chip microcomputer to infiltrate all areas of our lives, which is very difficult to find the area of almost no traces of single-chip microcomputer. Missile navigation equipment, aircraft control on a variety of instruments, computer network communications and data transmission, industrial automation, real-time process control and data processing, are widely used in a variety of smart IC card, limousine civilian security systems, video recorders, cameras, the control of automatic washing machines, as well as program-controlled toys, electronic pet, etc., which are inseparable from the single-chip microcomputer. Not to mention the field of robot automation, intelligent instrumentation, medical equipment has been. Therefore, the single-chip learning, development and application to a large number of computer applications and intelligent control of scientists, engineers.ingle-chip widely used in instruments and meters, household appliances, medical equipment, aerospace, specialized equipment and the intelligent management in areas such as process control, generally can be divided into the following areas:1. In the smart application of instrumentationSingle-chip with small size, low power consumption, control, and expansion flexibility, miniaturization and ease of use, widely used in instrumentation, the combination of different types of sensors, can be realized, such as voltage, power, frequency, humidity, temperature, flow, speed, thickness, angle, length, hardness, element, measurement of physical pressure. SCM makes use of digital instrumentation, intelligence, miniaturization and functional than the use of electronic or digital circuitry even stronger. For example, precision measurement equipment (power meter, oscilloscope, and analyzer).2. In the industrial controlMCU can constitute a variety of control systems, data acquisition system. Such as factory assembly line of intelligent management, intelligent control of the lift, all kinds of alarm systems, and computer networks constitute a secondary control system.3. In the application of household appliancesIt can be said that almost all home appliances are using the single-chip control, electric rice from favorable, washing machines, refrigerators, air conditioners, color TV and other audio video equipment, and then to the electronic weighing equipment, all kinds, everywhere.4. On computer networks and communication applications in the field ofGenerally with the modern single-chip communication interface, can be easilycarried out with computer data communications, computer networks and in inter-application communications equipment to provide an excellent material conditions, the communications equipment is now basically a single-chip Intelligent Control, from the mobile phone, telephone, mini-program-controlled switchboards, building automated communications system call, the train wireless communications, and then you can see day-to-day work of mobile phones, Mobile communications, such as radios.5. Single-chip in the field of medical equipment applicationsSingle-chip microcomputer in medical devices have a wide range of purposes, such as medical ventilator, various analyzers, monitors, ultrasonic diagnostic equipment and hospital call systems.6. In a variety of large-scale electrical applications of modularSome special single-chip design to achieve a specific function to carry out a variety of modular circuit applications, without requiring users to understand its internal structure. Integrated single-chip microcomputer such as music, which seems to be simple functions, a miniature electronic chip in a pure (as distinct from the principle of tape machine), would require a complex similar to the principle of the computer. Such as: music signal to digital form stored in memory (similar to ROM), read out by the microcontroller into analog music signal (similar to the sound card).In large circuits, modular applications that greatly reduces the size, simplifying the circuit and reduce the damage, error rate, but also to facilitate the replacement.In addition, single-chip microcomputer in the industrial, commercial, financial, scientific research, education, defense aerospace and other fields have a wide range of uses.单片机1单片机定义单片机是指一个集成在一块芯片上的完整计算机系统。

物 理 化 学 学 报Acta Phys. -Chim. Sin. 2024, 40 (1), 2303037 (1 of 17)Received: March 16, 2023; Revised: April 15, 2023; Accepted: April 18, 2023; Published online: May 9, 2023. *Correspondingauthor.Email:****************.cnThe project was supported by the National Natural Science Foundation of China (T2222002, 21973079, 21991130) and the Natural Science Foundation of Fujian Province (2021J06008).国家自然科学基金(T2222002, 21973079, 21991130)及福建省自然科学基金(2021J06008)资助项目© Editorial office of Acta Physico-Chimica Sinica[Review]doi: 10.3866/PKU.WHXB202303037Progress in the Trapping and Manipulation Volume of Optical TweezersChun-An Huo, Sheng-Jie Qiu, Qing-Man Liang, Bi-Jun Geng, Zhi-Chao Lei, Gan Wang, Yu-Ling Zou, Zhong-Qun Tian, Yang Yang *Pen-Tung Sah Institute of Micro-Nano Science and Technology, State Key Laboratory of Physical Chemistry of Solid Surfaces, Xiamen University, Xiamen 361005, Fujian Province, China.Abstract: The continuous developments in physical chemistry, improved methodology, and advanced techniques have spurred interest in chemical reaction at the microscopic scale. Experimental manipulation techniques at the microscopic level are demanded to enable in-depth studies regarding the regulation of chemical reactions, material structures, and properties. The development and application of microscopic research methods have become an emerging trend in physical chemistry. Techniques featuring the use of optical, magnetic, and acoustic tweezers have been developed to manipulate objects at the microscopic scale. Optical tweezers use momentum transfer between light and objects to manipulate objects and can stably trap and manipulate mesoscopic particles, even single molecules, by exerting pico-newton force. With advantages including non-invasiveness, non-damaging, and ultra-high sensitivity, optical tweezers are ideal for studying individualmolecules, molecular aggregates, condensed matter, chemical bonds, and intermolecular interactions. This technique has the potential to revolutionize the fields of chemistry, physics, information technology, and life sciences. Arthur Ashkin was awarded the 2018 Nobel Prize in Physics for his contribution to the development of this technique. The trapping force of the conventional optical tweezers technique originates from the light intensity gradient. Because of the diffraction limit of light, the trapping and manipulation of micro-nano objects < 100 nm in size with traditional optical tweezers is difficult. However, simply increasing the optical power used for trapping induces serious thermal effects and photodamage. By developing unique materials and structures coupled with optical tweezers, researchers have broken the diffraction limit of light and achieved sub-nanometer single-molecule trapping. In this review, we summarize the recent advances in the application of various optical tweezers techniques in physical chemistry and demonstrate the technical principles of fiber, photonic crystal, and plasmonic optical tweezers, respectively. We focus on the development and application of plasmonic optical tweezers and single-molecule plasmonic optical trapping based on tunable nanogaps. Generally, optical tweezers can realize the trapping and manipulation of molecular-scale particles via two main technical routes. The first route is improving the laser focusing ability through unique optical path design and optical component fabrication. The second involves enhancing the trapping field through ingenious auxiliary structure design. Finally, we present the promising future developments and applications of optical tweezers technology.Key Words: Optical tweezers; Single-molecule; Trapping volume; Microscale manipulation; Plasmon;Solid-liquid interface光镊捕获和操控尺度极限的进展霍春安，邱圣杰，梁青满，耿碧君，雷志超，王干，邹玉玲，田中群，杨扬*厦门大学萨本栋微米纳米科学技术研究院，固体表面物理化学国家重点实验室，福建厦门361005摘要：光镊技术能够实现对介观乃至微观颗粒的稳定捕获和灵活操控，是对微纳物体和单个分子施加力并观测其响应的理想操控手段。

程序员英文自我介绍（精选9篇）程序员英文篇1Good afternoon .I am of great hornor to stand here and introduce myself to you .First of all ,my english name is ...and my chinese name is ..If you are going to have a job interview ,you must say much things which can show your willness to this job,such as ,it is my long cherished dream to be ...and I am eager to get an opportunity to do...and then give some examples which can give evidence to .then you can say something about your hobbies .and it is best that the hobbies have something to do with the job. What is more important is do not forget to communicate with the interviewee,keeping a smile and keeping your talks interesting and funny can contribute to the success.I hope you will give them awonderful speech .Good luck to you !程序员英文自我介绍篇2My name is John Jones and I am an experienced problem solver for marketing departments. I know that you have an opening here in your West Coast Marketing Group, and I understand that you are concerned that your California advertising campaign is not producing as you expected.I have worked on several successful advertising campaigns and have had some great results in improving positioning.I know that I could step into this role and show you some progress from day one.程序员英文自我介绍篇3Good morning, ladies and gentlemen! It is really my honor to have this opportunity for an interview. I hope I can make agood performance today. I'm confident that I can succeed. Now I will introduce myself briefly. I am 26 years old, born in Shandong province. I graduated from Qingdao University. My major is electronics. And I got my bachelor degree after my graduation in the year of 20xx. I spent most of my time on study, and I’ve passed CET-6 during my university. And I’ve acquired basic knowledge of my major. It is my long cherished dream to be an engineer and I am eager to get an opportunity to fully play my ability.In July 20xx, I began working for a small private company as a technical support engineer in Qingdao city. Because there was no more chance for me to give full play to my talent, so I decided to change my job. And in August 20xx, I left for Beijing and worked for a foreign enterprise as an automation software test engineer. Because I want to change my working environment, I'd like to find a job which is more challenging. Moreover，Motorola is a global company, so I feel I can gain a lot from working in this kind of company. That is the reason why I come here to compete for this position. I think I'm a good team player and a person of great honesty to others. Also，I am able to work under great pressure. I am confident that I am qualified for the post of engineer in your company.That’s all. Thank you for giving me the chance.程序员英文自我介绍篇4Good morning !It is really my honor to have this opportunity for a interview,I hope i can make a good performance today. I'm confident that I can succeed.Now i will introduce myself brieflyI am 24 years old,born in Jiangxi province .I was graduated from University of Science and Technology of China university. my major is Software Engineer.and I will get my master degree after my graduation in the year of 20xx.I spend most of my time on study,i have passed CET4 . and i have acquired basic knowledge of my major during my school time.In July 20xx, I begin work for ...as a java engineer in suzhou city.Because I'm capable of more responsibilities, so I decided to change my job.Because I want to change my working environment, I'd like to find a job which is more challenging.Morover is a global company, so I feel I can gain the most from working in this kind of company ennvironment. That is the reason why I come here to compete for this position.I think I'm a good team player and I'm a person of great honesty to others. Also I am able to work under great pressure.That’s all. Thank you for giving me the chance程序员英文自我介绍篇5My name is , I'm from the , I graduated from the Fujian University, I majored in visual programming. I am applying for jobs is a java software engineer, and glad to give me an interview. Now, and I just graduated from is very different, and I already have two years of Java development experience, so I think I have the ability to accomplish superior to the most of my work, and I was in the golden age of the programmer. also energetic age, can work under pressure, I think I can give companies create value, and very willing to join your company to dedicate my youth. So really hope you can give me another opportunity to inject fresh blood into the company. Thank you!程序员英文自我介绍篇6I am Sravani, I am from Secunderabad. My hobbies are listening to music most of the time and playing badminton, indoor games such as caroms , chess etc.My strengths are, I am optimistic in nature, and my parents. Coming to my family background we are four of us: me, my father, mother and a younger brother. My father is SCR employee, mom house wife and brother is perceiving his B.Pharm 3rd year.Moving on to my educational background: I have done my schooling from Keyes high school in the year 20xx, I finished bipc from srichaitanya in the year 20xx, i have completed B.Sc. Nursing from Yashoda institutions under NTR university in the year 20xx. The whole of 20xx I was working as staff nurse in Yashoda hospital.Right now I am looking out for BPO because I got engaged last year, my in-laws are against me not to work in nursing department. So, i am looking out for BPO because as it provides good platform for freshers and more over it would welcome a person at any educational level with good communication skills and ability to handle customers.程序员英文自我介绍篇7Leaders, my name is , the remaining more than gold, gold. My hometown is in Gushi County of Henan Province, the parents are alive are all in good health, I have a sister in Wuhan. I am 07 years university graduate, majoring in computer software and Javar technology. Remember that before graduation to find work in Shanghai, then in Shanghai Wanda company internship, six months after the positive to health services, programmers working in medical and health projects. It is a total of about a year and a half, quit. The reason is probably that the workatmosphere made me feel not what plus was also feeling good jump to a Japanese company to work, just at that time the company in CMMI3, do the project in strict accordance with the CMMI process to go, what documents, Coding, I have to participate in the test. That time is really learned a lot of things on the project, may be just what the financial crisis, the company originally promised wages did not materialize and left. Go to the Shanghai Information Company, from the beginning of the project the main force to the development of the project leader, my biggest harvest in the agricultural letter nearly three years of work is, let me face to face communication better needs freedom in the project with the client side, late in the project to provide training and project by customer feedback and project to know. May be I can't adapt to the changes of company, then put forward to leave away.Technology I have been engaged in the J2ee Web, the general open source framework Struts1, Struts2, Hibernate, Ibatis and Spring are used in project development. Master Ajax, Jquery, Dwr front-end, including CSS and HTML.The database can write complex SQL query statistics including views, stored procedures, postgre, Oracle, Sql, Server project development experience.My personality is outgoing seems not to like to make friends, like challenging. Leisure time to play badminton, table tennis, chess.If asked why, at the moment I feel the work is not stable, this project I do is the pioneering, with certain experimental may succeed or fail, even if the returned to the head of project success and I can't find your location.Weaknesses: speak too straight, the lack of courage to dothings too much will hesitate.Character strengths: work a sense of self is a serious and responsible, can bear hardships and stand hard work.程序员英文自我介绍篇8I’m Cheers.Lee, I’m twenty-six year old, I majored in E-business and with a bachelor degree. I’m single. And I love software testing, as the software quality is vital to the company’s customer, it also could improve the company’s image, so quality is the best policy. We must devote all my energy to assure the software quality.The position which I’ve come to apply is senior software testing engineer. I have three years work experience, one year and a half of function testing experience and one year of performance and automation testing experience. I have been reading up on software testing, especially on performance testing and automation testing. I’m quite familiar with performance testing tool LoadRunner, and familiar with automation testing tool QTP. I’m good at developing performance testing script base on C language in web system, and also have good skills in develop QTP script.As we all know that software performance has become more and more important, while thousands of the users log in the system or visit the website simultaneously, the problem may occurred, the system crash or the server deny to provide the service to the user, so the performance testing need to be done before the software delivered to our customers.We also benefit from the automation testing. There is always a lot of function testing or regression testing need us to finish in a short time. But we do not have enough time and sufficient human resource to complete it, how should we do? So theautomation testing is the best solution. It cut down the costs, improve the work efficiency, save our time and energy. Its advantage is not merely as so.程序员英文自我介绍篇9My name is , this year is 21 years old, graduated from PLA information engineering university computer science and technology professionals, in the four years of college life, I have grasped the development and application of technology, but also in the development of the network have the profound understanding. So to lay a solid foundation of professional knowledge. In the thoughts and behavior, thought progress, positive enterprising, has the self-confidence, have very strong work sense of responsibility and the dedication to work, work steadfast, bears hardships and stands hard work, have a high comprehensive quality training.During the period of school has many social practice experience, has participated in college online virtual laboratory development needs analysis, the university period as many times more course lesson representative. Professional knowledge, proficient in C/C programming language, capable of using the language for software development; Master Visual C 6.0 programming software, has the rich based on Windows platform write software experience. Understand TCP/IP protocol, familiar with the basic principle of database; Have relatively rich web design and development experience, was instrumental in construction and maintenance institute's web site.Actively participate in a number of research projects. Has a strong professional ability. Have a solid Core Java foundation, good programming style; Familiar with Tomcat, Jboss server and so on, familiar based on Linux and Unix environment of softwaredevelopment.Although the actual work experience is not very full, but point four years developed my full confidence and professional dedication and solid base of the discipline knowledge and strong professional skills, four years of military school life, I strict demands on themselves, and consciously, observance of discipline and punctuality. I am honest and have the sense of responsibility, has the independent enterprising character, is industrious hands, good at one's brains, adapt to the new environment ability. Can be in the shortest time to finish from students to professional staff transformation, try your best into the new work and life.After four years of study, training I become a moral right, has a strong will and a lofty ideal, has the enterprising spirit and team cooperation spirit of good students. Believe what I have knowledge and competence can fit for any hard work. If I am lucky enough to become a member of your company, I will put all the youth and enthusiasm bend force into work, obtain due scores, for the development of the company to contribute their strength.译文：我叫，今年21岁，毕业于解放军信息工程大学计算机科学与技术专业，在四年的学习生活中，我系统地掌握了开发与应用方面的技术，同时也对当今网络的发展有了深刻的认识。

全球战塑英语作文考试卷子篇1Plastic pollution has become an overwhelming global crisis! How serious is it? Just think about the vast amounts of plastic waste accumulating in our oceans. This is not only an eyesore but a fatal threat to marine life. Have you ever imagined the poor sea creatures getting entangled in plastic debris or mistakenly swallowing it, leading to their painful deaths? It's heart-breaking!And what about the tiny plastic particles? They enter the food chain and could potentially pose a huge hazard to human health. How terrifying is that? We might unknowingly consume these microscopic plastics, with unknown long-term consequences.Isn't it high time we took drastic actions to combat this menace? We should reduce our reliance on single-use plastics. Shouldn't we promote recycling and proper waste disposal? Every small step counts! We can no longer turn a blind eye to this pressing issue. If we don't act now, what kind of world will we leave for future generations? This is a question that demands our immediate attention and decisive actions. Let's unite and fight against plastic pollution for the sake of our planet and all living beings!篇2In today's world, the issue of plastic pollution has become a globalconcern. The fight against plastic is not only necessary but also extremely urgent! How can we effectively combat this problem?Some countries have successfully implemented plastic restrictions. For instance, certain regions have imposed strict bans on single-use plastics, which has led to a significant reduction in plastic waste. The development and application of degradable plastics is also a promising approach. However, implementing these strategies is not without difficulties.In developing countries, promoting environmental concepts and technologies poses significant challenges. Many people lack awareness of the severity of plastic pollution. How can we enhance their understanding and change their behavior? The lack of funds and advanced technologies also hinders the wide application of degradable plastics.Moreover, the global nature of plastic pollution requires international cooperation. But achieving consensus among different countries is a complex task. How can we overcome these obstacles and work together for a plastic-free world?The battle against plastic is a long and arduous journey. But we must not give up! We need to keep exploring and implementing effective strategies to protect our planet for future generations. Isn't it our responsibility?篇3We are living in a world where plastic pollution has become a seriousthreat! How can we, as individuals, contribute to the global battle against plastic? Let me tell you about some of my experiences and observations.Just imagine, we use disposable plastic products every day, such as plastic bags, straws, and cups. But have we ever thought about the consequences? I decided to make a change. I started by refusing to use disposable plastic bags when shopping. Instead, I carried a reusable bag with me. My friends and family were influenced by my actions and they also began to reduce the use of disposable plastic products.Not only that, but I also actively participated in community environmental protection activities. We organized events to promote the classification and recycling of plastic waste. Isn't it amazing how a small action by each of us can make a big difference?However, we still have a long way to go. There are still many people who are not aware of the severity of the problem. How can we raise their awareness? How can we encourage more people to take action? This is a question that we all need to think about!Let's take responsibility for our planet and do our best to fight against plastic pollution. After all, it's our home and we should protect it!篇4It is an undeniable fact that the global battle against plastic has emerged as a critical issue in today's world. How does this battle relate to economic development? This is a profound question that demands ourserious consideration!The transformation of the plastic products industry has had a significant impact on the economic structure. For instance, as the awareness of environmental protection grows, traditional plastic manufacturing enterprises have been forced to adapt and innovate. They have to invest in research and development of more eco-friendly materials and production methods. This not only incurs additional costs but also requires a major overhaul of the production lines. However, in the long run, this transformation could lead to the creation of higher-quality and more sustainable products, opening up new markets and opportunities.On the other hand, the rise of the environmental protection industry has brought about new economic growth points. The development of biodegradable plastics, recycling technologies, and waste management services has created a plethora of jobs and business opportunities. Isn't this a remarkable shift? It shows that the fight against plastic can stimulate economic growth and innovation.In conclusion, the global battle against plastic is not just an environmental imperative; it is also an opportunity for economic restructuring and growth. We should embrace this challenge with determination and vision, as it holds the potential to shape a more sustainable and prosperous future for us all!篇5In today's world, the issue of plastic pollution has become a global concern that demands our immediate attention and action. Plastics, once hailed as a revolutionary material, have now turned into a menacing threat to our planet. The far-reaching impact of the global battle against plastic on the future of our society is truly profound and thought-provoking!Think about the concept of plastic-free cities in the future. What would that look like? Imagine streets free of plastic waste, where our natural environment flourishes without the blight of plastic debris. Isn't it a vision worth striving for? But how can we achieve this? It requires a collective effort, from changing our consumption habits to implementing strict regulations on plastic production and disposal.Let's also consider the evolution of the role of plastic products throughout history. They once brought convenience and innovation, but now they have caused overwhelming environmental damage. How ironic is this? What lessons can we draw from this transformation for the future? We must learn to use materials more sustainably and be conscious of the long-term consequences of our choices.The global fight against plastic is not just a matter of environmental protection; it is a battle for the well-being of future generations. Are we going to leave them a planet choked with plastic or a healthy and thriving world? The choice is ours, and the time to act is now! We must takedecisive steps to ensure a plastic-free future, for the sake of our planet and all life on it.。

抗蚀剂英语Corrosion InhibitorsCorrosion is a ubiquitous phenomenon that affects a wide range of materials and industries. It is a natural process in which materials, primarily metals, undergo gradual deterioration and degradation due to chemical or electrochemical reactions with their surrounding environment. Corrosion can have devastating consequences, leading to the failure of critical infrastructure, the loss of valuable assets, and the potential for environmental damage. To mitigate the detrimental effects of corrosion, the use of corrosion inhibitors has become a crucial strategy in various applications.Corrosion inhibitors are chemical substances that, when added in small concentrations to a corrosive environment, effectively reduce or prevent the rate of corrosion. These inhibitors work by forming a protective layer on the surface of the metal, which acts as a barrier against the corrosive agents. The mechanism by which corrosion inhibitors function can be categorized into three main types: anodic, cathodic, and mixed inhibitors.Anodic inhibitors work by suppressing the anodic reaction, which isthe oxidation of the metal. They form a passivating film on the metal surface, preventing the dissolution of the metal ions. Examples of anodic inhibitors include chromates, phosphates, and silicates. Cathodic inhibitors, on the other hand, target the cathodic reaction, which is the reduction of oxygen or hydrogen ions. They form a protective layer on the cathode, hindering the cathodic process and slowing down the overall corrosion rate. Common cathodic inhibitors include zinc salts, magnesium salts, and rare earth compounds. Mixed inhibitors, as the name suggests, employ a combination of both anodic and cathodic inhibition mechanisms to provide comprehensive protection against corrosion.The selection of an appropriate corrosion inhibitor depends on various factors, such as the nature of the metal, the corrosive environment, the desired level of protection, and the cost-effectiveness of the inhibitor. In some cases, a single inhibitor may not be sufficient, and a combination of different inhibitors is used to achieve the desired level of corrosion protection.One of the most widely used corrosion inhibitors is chromate, which has been extensively employed in various industries due to its excellent inhibition properties. Chromate inhibitors form a stable, adherent oxide film on the metal surface, effectively preventing the initiation and propagation of corrosion. However, concerns have been raised about the environmental and health impacts ofchromate-based inhibitors, as they contain hexavalent chromium, which is a known carcinogen. This has led to the development of alternative, more environmentally friendly corrosion inhibitors.In recent years, there has been a growing interest in the use of organic corrosion inhibitors, which are derived from natural sources or synthetic compounds. These inhibitors are often less toxic and more environmentally friendly compared to traditional inorganic inhibitors. Organic inhibitors can be further classified into several categories, including amine-based, imidazoline-based, and heterocyclic compounds. These inhibitors work by adsorbing onto the metal surface, forming a protective film that prevents the access of corrosive agents.Another emerging class of corrosion inhibitors is the use of nanoparticles and nanomaterials. Nanoparticle-based inhibitors offer unique advantages, such as enhanced surface coverage, targeted delivery, and the ability to incorporate multiple active components within a single nanostructure. These nanoparticle-based inhibitors have shown promising results in various applications, including the protection of steel, aluminum, and copper alloys.The development and application of corrosion inhibitors are not limited to traditional industries. In recent years, there has been a growing interest in the use of corrosion inhibitors in the renewableenergy sector, particularly in the protection of solar panels and wind turbine components. Corrosion can significantly reduce the efficiency and lifespan of these critical infrastructure, making the use of effective corrosion inhibitors essential for the long-term sustainability of renewable energy systems.In addition to their industrial applications, corrosion inhibitors also play a crucial role in the protection of cultural heritage artifacts and historical monuments. These valuable assets are often exposed to various environmental factors, such as humidity, pollutants, and salts, which can accelerate the deterioration of the materials. The use of corrosion inhibitors, combined with other conservation techniques, helps to preserve the integrity and longevity of these irreplaceable cultural treasures.The future of corrosion inhibitors holds great promise, as researchers and industries continue to explore new and innovative approaches to address the challenge of corrosion. The development of smart, self-healing corrosion inhibitors, the integration of corrosion inhibitors with advanced materials, and the exploration of sustainable and eco-friendly inhibitor formulations are just a few examples of the ongoing advancements in this field.In conclusion, corrosion inhibitors are essential tools in the fight against the detrimental effects of corrosion. They provide a cost-effective and efficient means of protecting a wide range of materials and assets, from industrial infrastructure to cultural heritage. As the demand for corrosion protection continues to grow, the development and application of innovative corrosion inhibitors will play a crucial role in ensuring the long-term sustainability and resilience of our built environment and technological systems.。

SPE 124955Development and Application of Upscaling Techniques for Modeling Near-Well Flow in Heterogeneous ReservoirsYuguang Chen, SPE, Alan Bernath, Himansu Rai, SPE, Pierre Muron, Chevron Energy Technology CompanyCopyright 2009, Society of Petroleum EngineersThis paper was prepared for presentation at the 2009 SPE Annual Technical Conference and Exhibition held in New Orleans, Louisiana, USA, 4–7 October 2009.This paper was selected for presentation by an SPE program committee following review of information contained in an abstract submitted by the author(s). Contents of the paper have not been reviewed by the Society of Petroleum Engineers and are subject to correction by the author(s). The material does not necessarily reflect any position of the Society of Petroleum Engineers, its officers, or members. Electronic reproduction, distribution, or storage of any part of this paper without the written consent of the Society of Petroleum Engineers is prohibited. Permission to reproduce in print is restricted to an abstract of not more than 300 words; illustrations may not be copied. The abstract must contain conspicuous acknowledgment of SPE copyright. AbstractUpscaling is often applied in reservoir simulation to coarsen highly detailed geological descriptions. Flow in petroleum reservoirs is mainly driven by wells, thus upscaling of near-well flow is important in coarse-scale flow simulation. In this paper, we present an upscaling methodology, which involves a recently developed coarse-scale well model, combined with transmissibility upscaling for inter-well regions. The coarse-scale well model, referred to as near-well arithmetic averaging, directly uses fine-scale permeabilities along well trajectories to compute coarse-scale well index. Compared to flow-based near-well upscaling techniques, this method does not require solving any fine-scale flow problem, but can approximately capture the effects of fine-scale heterogeneity in near-well regions. Therefore it is straightforward for use and does not incur any computational overhead. This model is implemented in a general reservoir modeling framework, which allows for the handling of realistic grid geometry and well completion from real field data. In inter-well regions, we apply transmissibility upscaling, which directly computes the upscaled transmissibility (defined at block interfaces) rather than permeability upscaling. Standard upscaling methods (local permeability and border region permeability upscaling) are also considered to illustrate their potential errors when not being applied appropriately (e.g., without near-well treatment). We apply the proposed upscaling methodology (near-well arithmetic averaging for near-well flow and transmissibility upscaling for inter-well regions) to sector models from real field cases. All the cases involve general multiphase flow simulations, including primary production, water flooding to oil-water and three-phase flow models. It is shown that the proposed methodology consistently improves the accuracy of standard upscaling methods that are commonly used in the industry and for some cases, provides accurate flow predictions, demonstrating its practical applicability for real field cases.IntroductionSubsurface reservoirs are characterized by strong heterogeneity over multiple length scales. Geological descriptions are generated by integrating data from different sources and at different scales, such as core, well log, and seismic data along with geological interpretation. Although computational resources have increased significantly in recent years enabling flow simulation of large-scale, multi-million cell models, those fine-scale geological descriptions are still too detailed to be applied directly for typical history matching and prediction simulation studies. Thus upscaling techniques are often needed in reservoir simulation to coarsen the highly detailed geological models to scales that are suitable for flow simulation, while maintaining the effects of important fine-scale features.Based on upscaled parameters, upscaling can be classified as upscaling of single-phase flow parameters and upscaling of multiphase parameters. Among many upscaling parameters, absolute permeability is one of the most important for bothsingle-phase and multiphase flow simulations. Reviews (e.g., Christie, 1996; Farmer, 2002; Gerritsen and Durlofsky, 2005) provide detailed discussions on a variety of upscaling techniques. The upscaled permeability is computed such that a similar fine-scale flow rate is maintained on the coarse-scale model for a given pressure drop. Different methods vary between different boundary conditions and sizes of flow domain, from which the upscaled permeability is computed (e.g., Durlofsky, 1991; Pickup et al., 1994; King and Mansfield, 1999; Wen et al., 2003; Wu et al., 2007). Upscaling of multiphase flow parameters consider in addition multiphase rock-fluid properties, e.g., relative permeabilities and other properties to account for additional multiphase flow mechanisms. Due to the complexity in multiphase flow, those parameters are more challenging to compute and are not routinely applied in practice (see, e.g., Barker and Thibeau (1997) for a review). Another important aspect in coarse-scale flow modeling is appropriate gridding to resolve key geological and engineering features in the coarse model (e.g., Durlofsky et al., 1997; King et al., 2006; Gerritsen and Lambers, 2008; Branets et al., 2009).2 SPE 124955 In this work, we focus on upscaling techniques to effectively model near-well flow in heterogeneous reservoirs. This is of importance because flow in petroleum reservoirs is mainly driven by wells. The upscaled single-phase flow parameters are our main concern because of their practical applicability. Due to the ‘radial’ flow in the vicinity of wells, upscaling in near-well regions is fundamentally different from standard upscaling which assumes slowly varying ‘linear’ flow. Previous researchers have studied this issue and developed near-well upscaling procedures to compute upscaled quantities in near-well regions (e.g., Ding, 1995; Durlofsky et al., 2000; Muggeridge et al., 2002). Those procedures entail solving local well-driven flow to compute upscaled well indices (which relate well rate to the difference between wellbore and well block pressures) and well block transmissibilities.Rather than using a flow-based near-well upscaling method, here we consider a new coarse-scale well model which was developed recently (Chen and Wu, 2008). This method, referred to as Near-Well Arithmetic Averaging (NWAA), does not require solving any (well-driven) flow problem, but can approximately account for the effect of fine-scale permeability heterogeneity in near-well regions. This approach is based on a singularity analysis of well-driven flow. It is shown that the pressure solution to well-driven flow can be decomposed into singular and regular parts. The singular part (corresponding to flow in the near-well region) is dominated by the fine-scale permeabilities at well locations. Therefore NWAA directly uses the permeabilities of fine-grid cells along well trajectories to compute the upscaled well index without solving any fine-scale flow problem. In the previous study (Chen and Wu, 2008), the method was tested on synthetic models and for single-phase flow problems. It was found that it consistently improves on coarse models without near-well treatment and offers comparable accuracy to the flow-based, near-well upscaling within appropriate parameter ranges. Although for some cases it may not be as accurate as flow-based approaches, NWAA is attractive in practical applications due to its simplicity and straightforward nature for use. In this work, we present the application of NWAA to sector models from realistic field cases and for general multiphase flow simulations which were not studied in previous work.A current trend in the development of upscaling techniques is to incorporate global flow into local upscaling or directly use global flow solutions to compute the upscaled properties. Traditional local upscaling (including near-well upscaling) decomposes a large-scale global flow problem into a series of small-scale, local flow problems which are solved separately from each other and with assumed local boundary conditions. Global or quasi-global upscaling, by contrast, directly uses global fine-scale (single-phase) flow solutions to compute the upscaled quantities, or incorporates approximate global information into local upscaling calculations. Along this line, various methods (e.g., Holden and Nielsen, 2000; Chen et al., 2003; Wu et al., 2007; Zhang et al., 2008) have been developed recently. These approaches can often capture large-scale connectivity in permeability fields especially for highly heterogeneous reservoirs (e.g., channelized models). In this study, the use of NWAA for modeling near-well flow indicates that it is possible to localize the near-well flow as the local fine-scale permeabilities at the well locations are used for the upscaled well index calculations. Through mathematical analysis (Chen and Wu, 2008) and numerical results for permeability fields in practice, we show the singularity feature of the well-driven flow and the efficacy of capturing the ‘local’ permeability effects in modeling near-well flow. For highly heterogeneous reservoirs, the interaction between near-well and global flow is investigated in Chen and Wu (2008).The upscaled modeling of well-driven flow comprises two parts. In addition to the ‘localized’ NWAA approach to modeling near-well flow, we consider standard upscaling to capture the permeability connectivity in inter-well regions. Here we apply transmissibility upscaling, which directly computes upscaled transmissibilities defined at block interfaces (which can be viewed as the numerical analogue of permeability), rather than permeability upscaling. Recent studies showed that the upscaled transmissibility can provide better accuracy for highly heterogeneous reservoirs (e.g., Romeu and Noetinger, 1995; Abbaszadeh and Koide, 1996; Chen et al., 2003). For the permeability fields considered here, local transmissibility upscaling (without global flow) provides adequate accuracy. It is shown that the combined use of NWAA and transmissibility upscaling consistently improves the accuracy of standard methods that are commonly used in the industry. Through field examples for general multiphase flow problems, we demonstrate the practical applicability of the proposed methodology, and also discuss limitations and possible improvement in terms of capturing complex multiphase flow behaviors (beyond the upscaling of single-phase flow parameters).This paper is organized as follows. We first present the governing equations and the upscaling methodology for modeling flow in near-well and inter-well regions. The NWAA approach is specifically described. Applications to sector models from real field cases are presented in Section 3, including primary production, water flooding in an oil-water model, and water flooding in a three-phase flow model. Comparisons of field and well-wise predictions for key flow quantities between the fine and coarse models demonstrate the applicability of the near-well modeling approach. Finally, we provide discussion on possible improvement and draw conclusions.Upscaling MethodologyGoverning Equations. The fundamental principle that describes flow in subsurface reservoirs is conservation of mass. The governing equations are formed by combining mass conservation equation for a phase (in a black oil model) or a component (in a compositional model) and Darcy’s law for the phase. Here we focus on the upscaling of single-phase flow parameters. But it is important to note that the upscaled single-phase flow parameters (permeability or transmissibility) are applicable toSPE 124955 3 more general (two-phase, multiphase or compositional) flow systems, though some additional upscaled properties may be needed to account for the more general flow mechanisms.In the upscaling of single-phase parameters, we consider steady-state, incompressible, single-phase flow. Combining Darcy’s law with a statement of mass balance yields the following equation (with all quantities dimensionless):()[]w q p =∇⋅⋅∇x k , (1) where k (x ) is symmetric, positive definite permeability tensor, highly variable in space x , p is pressure, and q w is well source/sink term, representing well flow rate (positive for production). In the discrete form of Eq. 1, transmissibility T , defined at the interface of two grid blocks, is introduced to relate flow from one block to its adjacent one through pressure difference: q 12 = T 12(p 1-p 2), where the indices 1 and 2 represent two adjacent grid blocks. In flow simulations, a well index WI is also introduced to relate the well flow rate q w to the difference between the wellbore and well block pressures. The well index, often computed using Peaceman’s well model (Peaceman, 1983), depends on grid geometry, grid block permeability and discretization schemes.Upscaling procedures are developed to generate appropriate coarse-scale properties which are able to ‘reproduce’ the fine-scale simulation results as closely as possible when being used in coarse-scale models. We now describe a recently developed coarse-scale well model for the coarse-scale modeling of near-well flow.Upscaling in Near-Well Region. As discussed in Introduction, flow in the near-well region is often the most active flow area. Due to its ‘radial’ flow feature, it is not appropriate to apply standard flow-based upscaling in the near-well region. More specifically, the determination of coarse-scale well block permeabilities used in the calculation of coarse-scale WI should not be based on standard upscaling.Flow-based near-well upscaling entails solving a fine-scale well-driven flow (as described in Eq. 1) in a local region around a given well, often with generic well conditions and assumed boundary conditions at the outer boundaries. Then the upscaled well index WI * (where the superscript * indicates upscaled properties) is directly computed from the local fine-scale solution. Previous studies (e.g., Ding, 1995; Durlofsky et al., 2000; Muggeridge et al., 2002; Chen and Wu, 2008) presented in detail the numerical procedures and also demonstrated the inaccuracy of standard upscaling methods when being used in modeling near-well flow.In this work, we consider an alternative approach to the flow-based near-well upscaling. This model, referred to as Near-Well Arithmetic Averaging (NWAA), was first presented by Chen and Wu (2008). It was developed based on a singularity analysis of well-driven flow. It was shown that the well-driven flow is dominated by fine-scale permeabilities at well locations. Accordingly, permeabilities of fine-grid cells along well trajectories can be used to compute the upscaled well index. We now briefly describe this model.Consider a single well located at x w , the flow equation (Eq. 1) can be written as:()[]()w q p x x k δ=∇⋅⋅∇, (2)where δ is the Dirac delta function, and q δ(x w ) represents a singular source with flow rate q at location x w . To illustrate the analysis, we first look at a homogeneous reservoir. Eq. 2 can then be simplified to:[]()w q p x k δ=∇⋅⋅∇, (3)where k denotes a constant permeability. Following the principle of linear superposition, the pressure solution for Eq. 3 can be decomposed into a singular part p s and a regular part p r , i.e., p (x )=p r (x )+p s (x ). The singular solution p s satisfies )()(w s q p x k δ=∇⋅⋅∇, and the regular solution can be solved readily from 0)(=∇⋅⋅∇r p k , after the well singularity is removed from the original equation (Eq. 2).This decomposition can be related to different approaches to modeling near-well flow. In fact, the use of WI (derived from an analytical solution for radial flow) is to model the singular part of the pressure solution. In the context of flow-based upscaling, standard local upscaling, under the assumption of ‘linear’ flow, corresponds to the regular part of the pressure solution, while near-well upscaling, based on ‘radial’ flow, aims to effectively handle the singularity introduced by wells. Another approach, local grid refinement (LGR), is often applied to areas around wells such that the well singularity is better resolved. In other regions away from wells, regular grids can be applied to obtain the regular solution p r as the singularity is removed in those regions.Although an analysis for heterogeneous reservoirs is more complicated, it does suggest an approximation to represent the well index in coarse-scale models. Here we briefly present the results, and for detailed derivations, please refer to Chen and Wu (2008). Assume that in a heterogeneous reservoir, the permeability at well location x w is represented by k (x w )= k 0. Then the solution for Eq. 2 can still be decomposed into a singular part and a regular part, and the singular solution p s satisfies:4 SPE 124955)()(0w s q p x k δ=∇⋅⋅∇. (4)This is similar to the homogenous case, but with the constant permeability k replaced by the well permeability k 0. Following Chen and Wu (2008), the equation for the regular solution p r can be written as:()[]()()[]s r p p ∇⋅−⋅∇=∇⋅⋅∇x k k x k 0. (5)Eq. 5 is more complicated than its counterpart in the homogenous case. But as discussed in Chen and Wu (2008), the singularity of the source term in Eq. 5 is much weaker than the Dirac delta function in the original pressure equation (Eq. 2). Analogous to the homogeneous case, the decomposition suggests that the upscaling of well-driven flow consists of two parts – the singular part captured in near-well upscaling to account for the dramatically changing ‘radial’ flow, and the regular part taken into account in the standard upscaling which assumes slowly varying ‘linear’ flow. The equation for the singular solution (Eq. 4) also indicates that the near-well singular flow is dominated by the fine-scale permeability at the well location k 0. Therefore the coarse-scale well index in heterogeneous reservoirs can be approximated by using k 0 in the well index calculation. This type of analysis was also considered for well modeling in the context of multiscale simulation (Chen and Yue, 2003).In the previous work (Chen and Wu, 2008), coarse-scale well modeling for vertical and horizontal wells in 3D reservoirs was considered, and the 3D problem is approximated by a series of 2D problems. Specifically, for a coarse-scale well block, the permeability used in Peaceman’s well index calculations is the arithmetically averaged fine-scale permeabilities along the well trajectory within that coarse block. This approach is referred to as ‘Near-Well Arithmetic Averaging’ (NWAA), in contrast to the standard arithmetic averaging, in which all the fine-scale permeabilities within the coarse-scale well block areaveraged.(a) Arithmetic averaging (b) Near-well arithmetic averagingFigure 1: Illustration of arithmetic averaging and near-well arithmetic averaging to compute upscaled permeabilities for coarse-scale well blocks: (a) coarse-scale grid blocks penetrated by a deviated well with all the fine-scale permeabilities within the coarse blocks, and (b) coarse-scale grid blocks with only the fine-scale permeabilities penetrated by the deviated well.Fig. 1 illustrates the concept of NWAA. Shown in Fig. 1a are a set of coarse-scale grid blocks (with fine-scale cells) penetrated by a deviated well. There are a total of 100 layers in the fine-scale model, and each coarse block contains 3×3 fine-scale grid cells areally. Fig. 1b displays only the coarse grid blocks (a total of 22 layers) and the fine-scale grid cells penetrated by the deviated well. In NWAA, the coarse-scale well block permeability (used in well index calculations) is computed via:∑∑=fine w fine fine w finewfine w eff vv k k , (6)where v denotes bulk volume of a fine-grid cell, and the superscript w represents well related quantities. Eq. 6 means that the effective coarse-scale well permeability is computed through a bulk-volume weighted average of the fine-scale cell permeabilities along the well path within the coarse-scale well block (as displayed in Fig. 1b). This calculation applies to the well block permeability in the x , y and z directions, respectively. Note that in standard arithmetic averaging, all the fine-scale permeabilities within the coarse well blocks are considered for the averaging, as shown in Fig. 1a. Compared to flow-based near-well upscaling, this approach does not require solving any fine-scale well-driven flow. Note that similar idea to use theSPE 124955 5 fine-scale permeabilities at well locations in the coarse-scale well index calculation was also mentioned in Dupouy et al. (1998), though no systematic analysis and testing were provided.In the previous work (Chen and Wu, 2008), the NWAA approach was applied to synthetic models and was tested only for single-phase flow. In this work, NWAA was implemented in a general reservoir modeling framework and integrated with general well completion options. This allows us to apply this approach to realistic field models with real well completion data. In addition, we test the method for general multiphase flow simulation, which was not considered previously.Upscaling in Inter-Well Regions. The coarse-scale modeling of well-driven flow is also impacted by flow in inter-well regions. The inter-well region can be viewed as the regular part of the pressure solution after the well singularity is removed. In standard upscaling, the single-phase flow equation (without source/sink terms) ()[]0=∇⋅⋅∇p x k is solved on local fine-scale regions to compute the upscaled properties. Again, by the principle of superposition, the general flow is decomposed into solutions in three directions – x , y and z . Accordingly, standard upscaling assumes ‘linear’ flow in the x , y and zdirections respectively (i.e., generic flows without wells) to compute the upscaled quantities in each direction, e.g.,*x k , *yk , and *z k in permeability upscaling. Here we briefly describe standard permeability upscaling which is the most commonlyapplied method in practice, as well as transmissibility upscaling which is shown to provide better accuracy for some cases.12 (a) Standard local k * upscaling (b) Border region k * upscaling (c) Harmonic average for interface kFigure 2: Schematic showing permeability (k*) upscaling: (a) standard local upscaling, (b) border region upscaling, and (c)harmonic average to obtain interface permeability used to compute interface transmissibility.Shown in Fig. 2 are standard approaches to permeability upscaling. Fig. 2a displays one coarse block (with 3×3fine-scale grid cells). Linear flow (e.g., constant pressures in the inlet and outlet of the local domain and no-flow for the local boundaries parallel to the flow direction) is imposed to the local coarse block. Following the fine-scale solution, the upscaled permeability is computed to preserve the averaged fine-scale flow rate for a give pressure drop. The fact that a large-scale flow problem is decomposed into a series of small-scale local flow problems to be solved separately may cause issues in terms of capturing large-scale connectivity. To overcome this problem, border region (or extended local) k * upscaling, as illustrated in Fig. 2b, is developed. The neighbouring cells around the target coarse block reduce the impact of local boundary conditions to some extent and also better capture the large-scale connectivity across coarse-scale blocks. Wen et al. (2003) presented a detailed study on border region k * upscaling.Note that permeabilities (k or k *) are defined at the center of a grid block. In finite-volume discretization, ‘permeabilities’ at grid block interfaces are needed to compute the fluxes through the interfaces, and a harmonic average of permeabilities at the two adjacent grid blocks is employed in finite-difference methods for this purpose (as shown in Fig. 2c). Then transmissibility (T ), which relates the flow rate and pressure differences between the two neighbouring grid cells, are computed as:L A k T *12*12=, where A is the interface area and L is the distance between the two grid block centers. Note thatthe use of harmonic average to compute the interface ‘permeability’ is strictly valid only for a 1D problem. It is known that harmonic average gives more weight to a lower value. Therefore, if there is a significant permeability contrast between the two adjacent blocks, the harmonic averaged value tends to underestimate the connectivity between the two grid blocks.Since transmissibility is the direct input to flow simulation, an alternative approach is to directly compute the upscaled transmissibility T *, rather than through the upscaled permeabilities k *. This removes the harmonic averaging step, thus avoiding potential errors introduced in high contrasting permeability fields. Fig. 3 illustrates the local upscaling calculation for T *, where the local region often consists of two adjacent coarse blocks (Fig. 3a) or includes in addition some neighbouring cells (Fig. 3b). They are analogous to the standard local and border region k * upscaling shown in Fig. 2. From the solution of the local fine-scale flow problem (often driven by a constant pressure difference in the flow direction), the upscaled transmissibility is computed via:2112*12p p q T −=, (7)6 SPE 124955 where <q> is the integrated fine-scale flow through the interface and <p> the volume average of fine-scale pressure over thecoarse block.1212(a)Local transmissibility upscaling (b) Extended local transmissibility upscalingFigure 3: Schematic showing transmissibility (T*) upscaling, where T* is defined at the interface of two grid blocks.As indicated in Introduction, the fine-scale quantities averaged in Eq. 7can be obtained from the solution over local, extended local (as shown here), or global domains. Recently, a trend in upscaling is to use global flow information to improve the accuracy of upscaled quantities with either a global method or quasi-global method. For the permeability fields considered in this work, we only apply local transmissibility upscaling, which provides sufficient accuracy. For cases with high permeability contrast, global upscaling can be applied to improve the accuracy.In this section, we have shown that the solution of a well-driven flow can be decomposed into a near-well singular solution and a regular solution for regions away from wells. The dominant impact on near-well flow comes from the local permeability (at the well location). Thus it is natural to localize the upscaling for near-well flow. Next, we apply the NWAA approach combined with transmissibility upscaling to sector models from real field cases.Numerical ResultsWe now present results for three example cases. All the cases involve multiphase flow simulations including primary production, water flooding for oil-water only conditions in a model, and water flooding in a three-phase model. We consider two sector models from real fields. For both fine and coarse-scale models, a general purpose reservoir simulator with a fully implicit formation is employed, and corner-point geometry grids are applied with a two-point flux approximation. In all the cases, coarse-scale flow simulation results are compared with reference to fine-scale results for key prediction quantities. Example 1: Primary Production.The first case is a model with a permeability field from an interbedded sand-shale reservoir. The fine-scale permeability distribution and histogram (in log scale) are displayed in Fig. 4. Two continuous shale layers are evident in the permeability field. This model has approximately six orders of magnitude variation in the permeability values. However the majority of these permeabilities are within a range of 0.1 −100 md, so it is not as contrasting as some highly heterogeneous reservoirs (such as channelized fields with bimodal distributions). Thus it is easier to capture the connectivities of the fine-scale model within an upscaled model (depending on the amount of upscaling) than more heterogeneous cases.Figure 4: Permeability field and histogram of log permeability used for Examples 1 (primary production) and 2 (water flooding). For primary production, there are 14 producers; and for water flooding, there 14 producers and 6 injectors.The fine-scale model is 55×40×1078 layers with more than two million total grid cells. A flow-based nonuniform coarsening approach (Durlofsky et al., 1997) is applied to coarsen the 1078 layers to 103 layers in the upscaled model, representing an upscaling factor of about 10. Note that fine-scale geological descriptions often have a much finer resolution in the vertical direction than areally so this type of ‘vertical-only’ upscaling is a fairly usual practice for these circumstances.。