labviewbased-virtual-function-signal-generator(基于labview的虚拟函数信号发生器的设计外文翻译.doc

1、浙江农林大学本科生毕业设计（论文） Labview-based virtual function Signal Generator 1 Introduction Since 1986, the U.S. NI (National Instrument) companies to the concept of virtual instrumentation, along with computer technology and measurement technology, virtual instrument technology has also been developed

2、rapidly. Virtual instrument means: use of the existing PC, with a specially designed instrument hardware and proprietary software, the formation of the basic functions of both the ordinary instrument, there are usually no special equipment features of the new instrument. Compared with the traditiona

3、l instruments of its features are: better measurement accuracy and repeatability; measurement speed; system set up time is short; instrument function defined by the user; scalability; technical updates and quick. Virtual instrument software as the core, the software company Youyi U.S. NI Labview vir

4、tual instrument software development platform most commonly used. Labview is a graphical programming language, mainly used to develop data acquisition, instrument control and data processing and analysis software, and powerful. Currently, the development of software in the international test, measur

5、ement and control industry, popular, measurement and control areas in the country has also been widely used. Function Generator is a scientific research and engineering design in a widely used general-purpose equipment. The following function signal generator with a virtual design and development of

6、 specific description is based on graphical programming language Labview virtual instrument programming and implementation of technology. 2 virtual function signal generator structure and composition 2.1 Virtual Function Generator front panel This virtual function signal generator mainly consists

7、 of a PCI bus, multi-function data acquisition card and appropriate software. Them installed on a PC running Windows95/98/2000/NT the machine, shall constitute a powerful function of signal generator. The design of the virtual function signal generator reference signal generator SG 1645 power functi

8、ons, front panel shown in Figure 1. Figure 1 virtual function signal generator front panel The function generator's front panel function of the following components: instrument control button, the output frequency control window (including the frequency of display units), frequency fold int

9、o control, waveform selection, frequency tuning button, dc bias, square wave accounts for Air ratio adjustment, the output waveform amplitude control buttons. Frequency tuning range: 0.1 ~ 1 Hz; DC bias: -10 ~ 10V; square wave duty cycle: 0 to 100%; output waveform range: 0 ~ 10V. Also increased the

10、 number of modification of voltage-controlled components such as panel input count input, synchronous output, voltage output. Modification of the use of these components is intended to increase the aesthetics of the instrument, and as far as possible with real instruments consistent user interface

11、2.2 Virtual Function Signal Generator hardware structure This virtual function signal generator hardware input and output data acquisition card and a certain configuration requirements of the PC, the data input and output depend on input data acquisition card, the definition of output achieved. Thi

12、s design uses the PCI-1200 data acquisition card is a good cost-effective products, with the D / A conversion functions, can generate the digital signals into analog signals and digital-analog converter and high precision, but also has filtering capabilities, which Smooth the output waveform. It sup

13、ports the unipolar and bipolar analog signal input, the signal input ranges of -5 ~ +5 V and 0 ~ 10V. Provide 16 single-ended / 8 differential analog input channels, 2 independent of the DA output channels, 24-line TTL digital I / O, 3 16-bit timer counters and other features. Some of the hardware i

14、nterface for data input or output channel settings. Some of the hardware interface block diagram shown in Figure 2: Figure 2 3 Virtual Function Signal Generator Design and Implementation Some use professional LabVIEW6i software virtual instrument graphical development tools. Virtual function

15、signal generator output waveform mainly in software production and the output signal frequency display. Changes in the frequency of the output waveform is a concrete realization of data acquisition waveform data written to the buffer among the buffers by setting the update frequency (to change the i

16、nternal clock frequency) to achieve the output data frequency. The process is mainly in the use of Labview data acquisition sub-module of the AO START function modules. Function from the implementation point of view, this design features a virtual function signal generator structure includes two mod

17、ules: Module waveform generator (FG module) and frequency change control unit (DISPLAY) module. Waveform generator module and call FGEN module. FGEN module for the digital waveform generator module. Digital waveform generator module 3.1 Waveform generated virtual function signal generator module

18、is the core of the software. The module can be realized using sine, square, sawtooth, triangle and other waveforms. Sine wave generation principle is by calling the sin (x) function to implement. In this design, the design of each component sine wave cycle from 1000, using similar language in the Fo

19、r loop C as x assignment, so that the implementation of a For loop, you can generate a cycle of sine wave generating the data needed, and then use While Circulation, make the program repeatedly executed, can be continuously output sine wave. Square wave, sawtooth, triangle and sine wave generation t

20、heory produce similar principles are achieved through the mathematical sequence of numbers representative of the waveform. Compared with the analog signal, generated using the software method of digital waveform sequence although there are some errors, but the election cycle as long as a sufficient

21、number of points, you can make errors to a minimum, the least impact on the results. Waveform generated by the software one of the biggest advantage is greatly reduced the cost of the instrument and the instrument of small intelligent. Waveform generator module's front panel shown in Figure 3, wavef

22、orm generation module block diagram shown in Figure 3 Change of 3.2 unit of frequency control module When the output frequency dynamic range is large, with a single spin button control, due to a small rotation angle, you will have a greater change in the frequency, to the frequency of accurate

23、 Shezhi brought greater Kunnan, and frequency by using a knob Times by combining the output frequency can greatly improve the control accuracy. In order to improve control accuracy of the output frequency, which in this design, by using the unit of frequency change control module, the output control

24、 accuracy can be achieved 0.001Hz. The module's front panel shown in, the module block diagram shown in Figure 4 . Figure 4 4 Total Results: As a Labview graphical programming software development and testing system is a powerful, convenient and efficient programming tools. Similarity between

25、 the good, open, exclusive, making the test development cycle is short, low cost and high quality. Labview-based virtual machine interaction with the function signal generator is good, easy to operate and so on, to a wide range of applications and in scientific research, production and other fields.

26、 1 Pan H Z, et al. LabVIEW-based virtual Function Signal Generator[J] . Control Enginerring Practice, 2. Evans P D, Brown D. Simulation of brushless DC drives[c] ． IEE Proceedings B, Electric Power Applications，137(5) : 299-308． 3. René Spée, Alan K. Wallace and Joel Davis. Modeling of brushles

27、s dc drive systems with pulse-width modulated excitation[J], Mathematical and Computer Modelling, Volume 11, 1988, Pages 1166-1171. 4. Jawad Faiz, M. R. Azizian and M. Aboulghasemian-Azami. Simulation and analysis of brushless DC motor drives using hysteresis, ramp comparison and predictive current

28、 control techniques[J], Simulation Practice and Theory, Volume 3, Issue 6, 15 January 1996, Pages 347-363. 5. J. Figueroa, C. Brocart, J. Cros and P. Viarouge. Simplified simulation methods for polyphase brushless DC motors[J]. Mathematics and Computers in Simulation, Volume 63, Issues 3-5, 17 Nove

29、mber 2003, Pages 209-224. 6. J. Shao, D. Nolan, and T. Hopkins. A Novel Direct Back EMF Detection for Sensodess Brushless DC (BLDC) Motor Drives[C]. Applied Power Electronic Conference (APEC 2002), 2002: 33-38. 7. Doo-Hee Jung and In-Joong Ha. Low Cost Sensorless Control of Brushless DC Motors Usi

30、ng a Frequency Independent Phase Shifter [J]．IEEE Transactions on power electronic, 2000, 15: 744-752. 8. Kuang-Yao Cheng and Ying -Yu Tzou. Design of a Sensorless Commutation IC for BLDC Motors [J]．IEEE Transactions On power electronic, 2003, 18: 1365-1375. 基于Labview的虚拟函数信号发生器的设计 1前

31、言 自从1986年美国NI(National Instrument)公司提出虚拟仪器的概念以来,随着计算机技术和测量技术的发展,虚拟仪器技术也得到很快的发展。虚拟仪器是指:利用现有的PC机，加上特殊设计的仪器硬件和专用软件,形成既有普通仪器的基本功能,又有一般仪器所没有的特殊功能的新型仪器。与传统的仪器相比其特点主要有:具有更好的测量精度和可重复性;测量速度快;系统组建时间短;由用户定义仪器功能;可扩展性强;技术更新快等。虚拟仪器以软件为核心,其软件又以美国NI公司的Labview虚拟仪器软件开发平台最为常用。Labview是一种图形化的编程语言,主要用来开发数据采集，仪器控制及数据处理分析

32、等软件,功能强大。目前,该开发软件在国际测试、测控行业比较流行,在国内的测控领域也得到广泛应用。函数信号发生器是在科学研究和工程设计中广泛应用的一种通用仪器。下面结合一个虚拟函数信号发生器设计开发具体介绍基于图形化编程语言Labview的虚拟仪器编程方法与实现技术。 2虚拟函数信号发生器的结构与组成 2.1虚拟函数信号发生器的前面板 本虚拟函数信号发生器主要由一块PCI总线的多功能数据采集卡和相应的软件组成。将它们安装在一台运行Windows95/98/2000/NT 的PC机上，即构成一台功能强大的函数信号发生器。本虚拟函数信号发生器的设计参考了SG 1645功率函数信号发生器，前面板

33、如图1所示。 本函数信号发生器的前面板主要由以下几个部分构成：仪器控制按钮，输出频率控制窗口（包括频率显示单位），频率倍成控制，波形选择，频率微调按钮，直流偏置，方波占空比调节，输出波形幅度控制按钮。频率微调范围：0.1～1 Hz；直流偏置：-10～10V；方波占空比：0～100%；输出波形幅度：0～10V。此外还增加了许多修饰性的元件如面板上的压控输入、记数输入、同步输出、电压输出等。使用这些修饰性的元件的目的是为了增加仪器的美观性，并尽量与真实仪器的使用界面相一致 2.2虚拟函数信号发生器的硬件构成 本虚拟函数信号发生器的输入输出的硬件部分为一数据采集卡和具有一定配置要求的PC机，数

34、据的输入输出靠对数据采集卡输出输入口的定义来实现。本设计采用的PCI-1200数据采集卡是一块性价比较好的产品，具备数/模转换的功能，能将产生的数字信号转换成模拟信号且数模转换精度高，而且还具备滤波功能，从而使输出波形光滑。它支持单极和双极性模拟信号输入，信号输入范围分别为-5～+5V和0～10V。提供16路单端/8路差动模拟输入通道、2路独立的DA输出通道、24线的TTL型数字I/O、3个16位的定时计数器等多种功能。硬件接口部分用于数据输入或输出时的通道设置。硬件接口部分程序框图如图2所示： 3虚拟函数信号发生器的软件设计与实现 软件部分采用专业的LabVIEW6i图形化虚拟仪器开发工

35、具。虚拟函数信号发生器主要由软件完成输出波形信号的产生和输出信号频率的显示。输出波形频率的变化的具体实现是将波形数据写入数据采集卡的缓冲区当中，通过设置缓冲区的更新频率（改变内部的时钟频率）来实现输出数据频率的变化。该过程主要运用了Labview中的数据采集子模块中的AO START 功能模块。从实现功能的角度来说，本次设计的虚拟函数信号发生器的功能结构主要包括两大功能模块：波形产生模块（FG模块）和频率单位变化控制（DISPLAY）模块。波形产生模块又调用FGEN模块。FGEN模块为数字波形产生模块。 3.1数字波形产生模块 波形产生模块是虚拟函数信号发生器软件的核心。利用该模块可实现正

36、弦波、方波、锯齿波、三角波等波形。正弦波的产生原理是通过调用sin(x)函数来实现。在本次设计，设计每一正弦波周期由1000点组成，利用类似C语言中的For循环为x 赋值，这样执行一次For循环，便可以产生生成一个周期正弦波所需的数据，然后利用While 循环，使程序反复执行，就可以连续输出正弦波形。方波、锯齿波、三角波的产生原理与正弦波产生原理相近,都是通过数学运算来实现代表波形的数字序列。与模拟信号相比，利用软件的方法产生的波形数字序列虽然存在着一定的误差，但只要一个周期内选的点数足够的多，就可以使误差降到最低，对结果的影响最小。利用软件产生波形的一个最大的优点是使仪器的成本大大降低，而且

37、使仪器小型化，智能化。波形产生模块的前面板如图3所示，波形产生模块的程序框图如图3所示。 3.2 频率单位变化控制模块 当输出频率动态范围较大时，用单个旋转按钮控制时，由于旋转一个很小的角度就会产生较大的频率变动，给频率的准确设置带来了较大困难，通过使用一个旋钮和频率倍乘相结合，可大大提高频率的输出控制精度。为了提高频率的输出控制精度，在本次的设计当中，通过使用频率单位变化控制模块，使输出控制精度可达到0.001Hz。该模块的前面板如图5所示，该模块的程序框图如图 4所示。 4 总 结 Labview作为一个图形化编程软件，是开发测试系统的一种功能强大、方便快捷的编程工具。其良好的

38、相通性、开放性、专用性，使测试系统的开发周期短、成本低、质量高。基于Labview的虚拟函数信号发生器具有机交互性好、易于操作等特点，能够广泛的应用与于科研、生产等领域。 目 录 1 总 论 1 1.1 项目概况 1 1.2 建设单位概况 3 1.3 项目提出的理由与过程 3 1.4 可行性研究报告编制依据 4 1.5 可行性研究报告编制原则 4 1.6 可行性研究范围 5 1.7 结论与建议 6 2 项目建设背景和必要性 9 2.1 项目区基本状况 9 2.2 项目背景 11 2.3 项目建设的必要性 11 3 市场分析 14

39、 3.1 物流园区的发展概况 14 3.2 市场供求现状 16 3.3 目标市场定位 17 3.4 市场竞争力分析  17 4 项目选址和建设条件 19 4.1 选址原则 19 4.2 项目选址 19 4.3 场址所在位置现状 19 4.4 建设条件 20 5 主要功能和建设规模 22 5.1 主要功能 22 5.2 建设规模及内容 26 6 工程建设方案 27 6.1 设计依据 27 6.2 物流空间布局的要求 27 6.3 空间布局原则 28 6.4 总体布局 29 6.5 工程建设方案 30 6.6 给水工程 33

40、 6.7 排水工程 35 6.8 电力工程 38 6.9 供热工程 46 6.10 电讯工程 47 7 工艺技术和设备方案 51 7.1 物流技术方案 51 7.2 制冷工艺技术方案 67 8 节能方案分析 73 8.1 节能依据 73 8.2 能耗指标分析 73 8.3 主要耗能指标计算 74 8.4 节能措施和节能效果分析 76 9　环境影响评价 83 9.1 设计依据 83 9.2 环境影响评价应坚持的原则 83 9.3　项目位置环境现状 84 9.4　项目建设与运营对环境的影响 84 9.5　项目建设期环境保护措施 84

41、 9.6 项目运行期环境保护措施 86 10 安全与消防 87 10.1　安全措施 87 10.2　消防 88 11 组织机构和人力资源配置 92 11.1 施工组织机构 92 11.2 基建项目部的主要职责 92 11.3 运营管理 93 11.4 人员来源、要求及培训 94 12 工程进度安排 96 12.1 建设工期 96 12.2 工程实施进度安排 96 13 投资估算与资金筹措 98 13.1 投资估算 98 投资估算包括建设项目的全部工程，主要内容有：主体建筑工程、道路硬化工程、绿化工程、其他费用及基本预备费。 98 13.2 资金筹措 99 14 财务评价 102 14.1 评价依据及方法 102 14.2 基础数据与参数选取 102 14.3 营业收入及总成本费用估算 103 14.4 利润总额估算 105 14.5 盈亏平衡分析 105 14.6 财务评价 106 15 综合效益评价 107 16 招投标管理 108 16.1 编制依据 108 16.2 招标原则 108 16.3 招标方案 109 16.4 评标要点 110 17 结论及建议 111 17.1 结论 111 17.2 建议 112 14