单片机系统
广义地说,微处理系统是用于处理信息的,这种信息可以是电话交谈,仪器读数或企业帐户,但是各种情况下都涉及相同的主要操作:信息处理、存储和传递。在常规的电子设计中,这些操作都是以功能平台方式组合起来的,例如计数器,无论是电子还是机械的,都要存储当前值,并按要求将该值增1。诸如采用计数器的电子钟之类的任一系统要使其存储和处理能力遍布整个系统,因为每个计数器都能存储和处理一些数字。
当前微处理化系统与上述的常规方法不同,它将处理,存储和传输三个功能分离形成不同的系统单元。这种形成三个主要单元的分离方法是冯-诺依曼在20世纪40年代所设想出来的,并且是针对微计算机的设想。从此几乎所有制成的计算机都是用这种结构设计的,尽管包含宽广的物理形式,从根本上来说他们均是具有相同的基本设计。
在微处理器系统中,处理是由微处理器本身完成的。存储是利用存储器电路,而进入和出自系统的信息传输则是利用特定的输入/输出(I/O)电路。要在一个微处理器化时钟中找出执行计数功能的一个特殊硬件是不可能的,因为时间存储在存储器中,而在固定的时间间隔下由微处理器控制增值。但是,规定系统运转过程的软件包含实现计数器功能的单元。由于系统几乎完全由软件所定义,所以对微处理器结构和其辅助电路这种看起来非常抽象的处理方法使其在应用时非常灵活。这种设计过程主要是软件工程,而且在生产软件时,就会遇到产生于常规工程中相似的构造和维护问题。
图1.1 微型计算机的三个组成部分
图1.1显示出了微型计算机中这三个单元是如何按照机器中的信息通信方式而联
接起来的。该系统由微处理器控制,它管理自己与存储器和输入/输出单元的信息传输。外部的连接与工程系统的其余部分(即非计算机部分)有关。
尽管图中显示的只有一个存储单元,实际中有RAM和ROM两种不同的存储器被使用。由于概念上的计算机存储器更像一个公文柜,上述的“存储器”一词是非常不恰当的;信息存放在一系列已标号的“箱子”中,而且可按问题由“箱子”的序列号进行信息的参考定位。
微计算机常使用RAM(随机存取存储器),在RAM中数据可被写入,并且在需要时可被再次读出。这种数据能以任一所希望的次序从存储器中读出,不必按写入时的相同次序,所以有“随机”存取存储器。另一类型ROM(只读存储器)用来保持不受微处理器影响的固定的信息标本;这些标本在电源切断后不会丢失,并通常用来保存规定微处理器化系统运转过程的程序。ROM可像RAM一样被读取,但与RAM不一样的是不能用来存储可变的信息。有些ROM在制造时将其数据标本放入,而另外的则可通过特殊的设备由用户编程,所以称为可编程ROM。被广泛使用的可编程ROM可利用特殊紫外线灯察除,并被成为EPROM,即可察除可编程只读存储器的缩写。另有新类型的期器件不必用紫外线灯而用电察除,所以称为电可察除可编程只读存储器EEPROM。
微处理器在程序控制下处理数据,并控制流向和来自存储器和输入/输出装置的信息流。有些输入/输出装置是通用型的,而另外一些则是设计来控制如磁盘驱动器的特殊硬件,或控制传给其他计算机的信息传输。大多数类型的I/O装置在某种程度下可编程,允许不同形式的操作,而有些则包含特殊用途微处理器的I/O装置不用主微处理器的直接干预,就可实施非常复杂的操作。
假如应用中不需要太多的程序和数据存储量,微处理器、存储器和输入/输出可全被包含在同一集成电路中。这通常是低成本应用情况,例如用于微波炉和自动洗衣机的控制器。当商品被大量地生产时,这种单一芯片的使用就可节省相当大的成本。当技术进一步发展,更强更强的处理器和更大更大数量的存储器被包含形成单片微型计算机,结果使最终产品的装配成本得以节省。但是在可预见的未来,当需要大量的存储器或输入/输出时,还是有必要继续将许多集成电路相互联结起来,形成微计算机。
微计算机的另一主要工程应用是在过程控制中。这是,由于装置是按特定的应用情况由微机编程实现的,对用户来说微计算机的存在通常就更加明显。在过程控制应用中,由于这种设备以较少的数量生产,将整个系统安装在单个芯片上所获取的利益常比不上所涉及的高设计成本。而且,过程控制器通常更为复杂,所以要将他们做成单独的集成电路就更为困难。可采用两种处理,将控制器做成一种通用的微计算机,正像较强版本的业余计算机那样;或者做成“包裹”式系统,按照像电磁继电器那样的较老式的技术进行设计,来取代控制器。对前一种情况,系统可以用常规的编程语言来编程,正如以后要介绍的语言那样;而另一种情况,可采用特殊用途的语言,例如那种使控制器功能按照继电器相互连接的方法进行描述。两种情况下,序均能存于RAM,这让程序能按应用情况变化时进行相应的变化,但是这使得总系统易受掉电影响而工作不正常,除非使用电池保证供电连续性。另一种选择是将程序在ROM中,这样他们就变成电子“硬件”的一部分并常被称为“固件”。
尽管大规模集成电路的应用使小型和微型计算机的差别变得“模糊”,更复杂的过程控制器需要小型计算机实现他们的过程。各种类型的产品和过程控制器代表了当今微计算机应用的广泛性,而具体的结构取决于对“产品”一词的解释。实际上,计算机的所有工程和科学上的应用都能指定来进行这些种类的某一或某些工作。而在本设计中压力和压力变送器当某一力加到某一面积上,就形成压力,假如这力是1牛顿均匀地加在1平方米的面积上,这压力被定义为1帕斯卡。压力是一种普遍的工艺状态,它也是这个星球上的一个生活条件:我们生活在向上延伸许多英里的大气海洋的底部。空气物质是有重量的,而且这种下压的重量形成大气压。水,是生活的必需品,也是在压力之下提供给我们中的大多数人。在典型的过程工厂中,压力影响沸点温度、凝固点温度、过程效率、消耗和其他重要因数。压力的测量和控制,或者压力的不足—真空,在典型的过程控制中是极为重要的。
工厂中的工作仪器通常包括压力计、精密纪录仪、以及气动和电动的压力变送器。压力变送器实现压力测量并产生正比于所传感压力的气动或电信号输出。
在过程工厂中,将控制仪表远远放在过程的附近是不现实的,并且大多数测量是不容易从远处传来的。压力测量是一个例外,但是,如果要离测量点几百英尺外指示或记录某种危险化学品的高压,就会有来自这个压力所载的化学品所引发的危险。为
了消除这一问题,开发了一种信号传输系统。这种系统常常可是气动或者电动的。使用这种系统,就可以在某一地点安装大多数的指示、记录和控制仪器。这也是最少数量的操作者有效的运行工厂成为现实。
当使用气动传送系统时,测量信号就由变送器将比例为0%~100%的测量值转换
为气动信号。变送器安装在靠近过程中的测量点上。变送器输出—对气动变送器是输出压力—通过管道传给记录或控制仪表。气动变送器的标准输出范围是20~100kPa ,这信号几乎在全球使用。
当使用电子压力变送器时,压力就被转换成电流或电压形式的电信号。其标准范
围对电流来说是4~20mA DC ,对电压信号来说是1~5V DC 。当今,另一种电信号
形式变的越来越常用,就是数字或离散信号。基于计算机或微处理器的仪器或控制系统的应用正推动这类信号的应用不断增加。有时,分析获取描述传感器/变送器特性
的参数是很重要的。当量程已知,去获取增益就非常简单。假定电子压力传感器的量程为0~600kPa ,增益定义为输出变化除以输入变化。这里,输出的电信号(4~20mA DC ),而输入的过程压力(0~600kPa ),这样增益就为:
此外我们在本设计中还必须对温度进行测量,温度测量在工业控制中是很重要
的,因为它作为系统或产品状态的直接指标,或者作为如反应率、能量流、涡轮机效率和润滑质量等间接指标。现行的温度分度已使用了约200年,最初的仪器是基于气体和液体的热膨胀。现在尽管有许多其他类型的仪器在使用,这些填充式系统仍常用于直接的温度测量。有代表性的温度传感器包括:填充式热系统、玻璃液体温度计、热电偶、电阻温度探测器、热敏电阻、双金属器件、光学和辐射高温计和热敏涂料。
电气系统的优点包括高的精度和灵敏度,能实现开关切换或扫描多个测量点,可
在测量元件和控制器之间长距离传输,出现事故时可调换元件,快速响应,以及具有测量高温的能力。其中热电偶和电阻温度探测器则被最广泛的使用。
来自:中国电子网
kPa
mA kPa mA kPa kPa mA mA Kr 027.0600160600420==--=
附:英文原文
Microcomputer Systems
Electronic systems are used for handing information in the most general sense; this information may be telephone conversation, instrume nt read or a company?s accounts, but in each case the same main type of operation are involved: the processing, storage and transmission of information. in conventional electronic design these operations are combined at the function level; for example a counter, whether electronic or mechanical, stores the current and increments it by one as required. A system such as an electronic clock which employs counters has its storage and processing capabilities spread throughout the system because each counter is able to store and process numbers.
Present day microprocessor based systems depart from this conventional approach by separating the three functions of processing, storage, and transmission into different section of the system. This partitioning into three main functions was devised by V on Neumann during the 1940s, and was not conceived especially for microcomputers. Almost every computer ever made has been designed with this structure, and despite the enormous range in their physical forms, they have all been of essentially the same basic design.
In a microprocessor based system the processing will be performed in the microprocessor itself. The storage will be by means of memory circuits and the communication of information into and out of the system will be by means of special input/output(I/O) circuits. It would be impossible to identify a particular piece of hardware which performed the counting in a microprocessor based clock because the time would be stored in the memory and incremented at regular intervals but the microprocessor. However, the software which defined the system?s behavior would contain sections that performed as counters. The apparently rather abstract approach to the architecture of the microprocessor and its associated circuits allows it to be very flexible in use, since the system is defined almost entirely software. The design process is largely one of software engineering, and the similar problems of construction and maintenance which occur in
conventional engineering are encountered when producing software.
The figure1.1illustrates how these three sections within a microcomputer are connected in terms of the communication of information within the machine. The system is controlled by the microprocessor which supervises the transfer of information between itself and the memory and input/output sections. The external connections relate to the rest (that is, the non-computer part) of the engineering system.
Fig.1.1 Three Sections of a Typical Microcomputer
Although only one storage section has been shown in the diagram, in practice two distinct types of memory RAM and ROM are used. In each case, the word …memory? is rather inappropriate since a computers memory is more like a filing cabinet in concept; information is stored in a set of numbered …boxes? and it is referenced by the serial number of the …box? in question.
Microcomputers use RAM (Random Access Memory) into which data can be written and from which data can be read again when needed. This data can be read back from the memory in any sequence desired, and not necessarily the same order in which it was written, hence the expression …random? access memory. Another type of ROM (Read Only Memory) is used to hold fixed patterns of information which cannot be affected by the microprocessor; these patterns are not lost when power is removed and are normally used to hold the program which defines the behavior of a microprocessor based system. ROM?s can be read like RAMs, but unlike RAMs they cannot be used to store variable information. Some ROM?s have their data patterns put in during manufacture, while others are programmable by the user by means of special equipment and are called programmable ROM?s. The widely used programmable ROM?s are erasable by means of special ultraviolet lamps and are referred to as EPROM?s, short for Erasable Programmable Read Only Memories. Other new types of device can be erased electrically without the need for ultraviolet light, which are called Electrically Erasable Programmable Read Only
Memories, EEPROM?s.
The microprocessor processes data under the control of the program, controlling the flow of information to and from memory and input/output devices. Some input/output devices are general-purpose types while others are designed for controlling special hardware such as disc drives or controlling information transmission to other computers. Most types of I/O devices are programmable to some extent, allowing different modes of operation, while some actually contain special-purpose microprocessors to permit quite complex operations to be carried out without directly involving the main microprocessor.
The microprocessor processes data under the control of the program, controlling the flow of information to and from memory and input/output devices. Some input/output devices are general-purpose types while others are designed for controlling special hardware such as disc drives or controlling information transmission to other computers. Most types of I/O devices are programmable to some extent, allowing different modes of operation, while some actually contain special-purpose microprocessors to permit quite complex operations to be carried out without directly involving the main microprocessor.
The microprocessor , memory and input/output circuit may all be contained on the same integrated circuit provided that the application does not require too much program or data storage . This is usually the case in low-cost application such as the controllers used in microwave ovens and automatic washing machines . The use of single package allows considerable cost savings to e made when articles are manufactured in large quantities . As technology develops , more and more powerful processors and larger and larger amounts of memory are being incorporated into single chip microcomputers with resulting saving in assembly costs in the final products . For the foreseeable future , however , it will continue to be necessary to interconnect a number of integrated circuits to make a microcomputer whenever larger amounts of storage or input/output are required.
Another major engineering application of microcomputers is in process control. Here the presence of the microcomputer is usually more apparent to the user because provision is normally made for programming the microcomputer for the particular application. In process control applications the benefits lf fitting the entire system on to single chip are usually outweighed by the high design cost involved, because this sort if equipment is
produced in smaller quantities. Moreover, process controllers are usually more complicated so that it is more difficult to make them as single integrated circuits. Two approaches are possible; the controller can be implemented as a general-purpose microcomputer rather like a more robust version i f a hobby computer, or as a …packaged? system, signed for replacing controllers based on older technologies such as electromagnetic relays. In the former case the system would probably be programmed in conventional programming languages such as the ones to9 be introduced later, while in the other case a special-purpose language might be used, for example one which allowed the function of the controller to be described in terms of relay interconnections, In either case programs can be stored in RAM, which allows them to be altered to suit changes in application, but this makes the overall system vulnerable to loss if power unless batteries are used to ensure continuity of supply. Alternatively programs can be stored in ROM, in which case they virtually become part of the electronic …hardware? and are often referred to as firmware. More sophisticated process controllers require minicomputers for their implementation, although the use lf large scale integrated circuits …the distinction b etween mini and microcomputers, Products and process controllers of various kinds represent the majority of present-day microcomputer applications, the exact figures depending on one?s interpretation of the word …product?. Virtually all engineering and sci entific uses of microcomputers can be assigned to one or other of these categories. But in the system we most study Pressure and Pressure Transmitters. Pressure arises when a force is applied over an area. Provided the force is one Newton and uniformly over the area of one square meters, the pressure has been designated one Pascal. Pressure is a universal processing condition. It is also a condition of life on the planet: we live at the bottom of an atmospheric ocean that extends upward for many miles. This mass of air has weight, and this weight pressing downward causes atmospheric pressure. Water, a fundamental necessity of life, is supplied to most of us under pressure. In the typical process plant, pressure influences boiling point temperatures, condensing point temperatures, process efficiency, costs, and other important factors. The measurement and control of pressure or lack of it-vacuum-in the typical process plant is critical.
The working instruments in the plant usually include simple pressure gauges,
precision recorders and indicators, and pneumatic and electronic pressure transmitters. A pressure transmitter makes a pressure measurement and generates either a pneumatic or electrical signal output that is proportional to the pressure being sensed.
In the process plant, it is impractical to locate the control instruments out in the place near the process. It is also true that most measurements are not easily transmitted from some remote location. Pressure measurement is an exception, but if a high pressure of some dangerous chemical is to be indicated or recorded several hundred feet from the point of measurement, a hazard may be from the pressure or from the chemical carried.
To eliminate this problem, a signal transmission system was developed. This system is usually either pneumatic or electrical. And control instruments in one location. This makes it practical for a minimum number of operators to run the plant efficiently.
When a pneumatic transmission system is employed, the measurement signal is converted into pneumatic signal by the transmitter scaled from 0 to 100 percent of the measurement value. This transmitter is mounted close to the point of measurement in the process. The transmitter output-air pressure for a pneumatic transmitter-is piped to the recording or control instrument. The standard output range for a pneumatic transmitter is 20 to 100kPa, which is almost universally used.
When an electronic pressure transmitter is used, the pressure is converted to electrical signal that may be current or voltage. Its standard range is from 4 to 20mA DC for current signal or from 1 to 5V DC for voltage signal. Nowadays, another type of electrical signal, which is becoming common, is the digital or discrete signal. The use of instruments and control systems based on computer or forcing increased use of this type of signal.
Sometimes it is important for analysis to obtain the parameters that describe the sensor/transmitter behavior. The gain is fairly simple to obtain once the span is known.
Consider an electronic pressure transmitter with a range of 0~600kPa.The gain is
defined as the change in output divided by the change in input. In this case, the output is electrical signal (4~20mA DC) and the input is process pressure (0~600kPa). Thus the
kPa mA kPa mA kPa kPa mA mA Kr 027.0600160600420==--=
gain. Beside we must measure Temperature Temperature measurement is important in industrial control, as direct indications of system or product state and as indirect indications of such factors as reaction rates, energy flow, turbine efficiency, and lubricant quality. Present temperature scales have been in use for about 200 years, the earliest instruments were based on the thermal expansion of gases and liquids. Such filled systems are still employed, although many other types of instruments are available. Representative temperature sensors include: filled thermal systems, liquid-in-glass thermometers, thermocouples, resistance temperature detectors, thermostats, bimetallic devices, optical and radiation pyrometers and temperature-sensitive paints.
Advantages of electrical systems include high accuracy and sensitivity, practicality of switching or scanning several measurements points, larger distances possible between measuring elements and controllers, replacement of components(rather than complete system), fast response, and ability to measure higher temperature. Among the electrical temperature sensors, thermocouples and resistance temperature detectors are most widely used.
From:China electronic network
Structure and function of the MCS-51 series Structure and function of the MCS-51 series one-chip computer MCS-51 is a name of a piece of one-chip computer series which Intel Company produces. This company introduced 8 top-grade one-chip computers of MCS-51 series in 1980 after introducing 8 one-chip computers of MCS-48 series in 1976. It belong to a lot of kinds this line of one-chip computer the chips have,such as 8051, 8031, 8751, 80C51BH, 80C31BH,etc., their basic composition, basic performance and instruction system are all the same. 8051 daily representatives- 51 serial one-chip computers . An one-chip computer system is made up of several following parts: ( 1) One microprocessor of 8 (CPU). ( 2) At slice data memory RAM (128B/256B),it use not depositting not can reading /data that write, such as result not middle of operation, final result and data wanted to show, etc. ( 3) Procedure memory ROM/EPROM (4KB/8KB ), is used to preserve the procedure , some initial data and form in slice. But does not take ROM/EPROM within some one-chip computers, such as 8031 , 8032, 80C ,etc.. ( 4) Four 8 run side by side I/O interface P0 four P3, each mouth can use as introduction , may use as exporting too. ( 5) Two timer / counter, each timer / counter may set up and count in the way, used to count to the external incident, can set up into a timing way too, and can according to count or result of timing realize the control of the computer. ( 6) Five cut off cutting off the control system of the source . ( 7) One all duplexing serial I/O mouth of UART (universal asynchronous receiver/transmitter (UART) ), is it realize one-chip computer or one-chip computer and serial communication of computer to use for. ( 8) Stretch oscillator and clock produce circuit, quartz crystal finely tune electric capacity need outer. Allow oscillation frequency as 12 megahertas now at most. Every the above-mentioned part was joined through the inside data bus .Among them, CPU is a core of the one-chip computer, it is the control of the computer and command centre, made up of such parts as arithmetic unit and controller , etc.. The arithmetic unit can carry on 8 persons of arithmetic operation and unit ALU of logic operation while including one, the 1 storing device temporarilies of 8, storing device 2 temporarily, 8's accumulation
Structure and fun cti on of the MCS-51 series Structure and function of the MCS-51 series one-chip computer MCS-51is a nameof a piece of one-chip computer series which In tel Compa ny produces. This compa ny in troduced 8 top-grade on e-chip computers of MCS-51 series in 1980 after in troduc ing 8 on e-chip computers of MCS-48 series in 1976. It belong to a lot of kinds this line of one-chip computer the chips have,such as 8051, 8031,8751, 80C51BH, 80C31BH,etc., their basic compositi on, basic performa nee and in structi on system are all the same. 8051 daily representatives- 51 serial on e-chip computers . An one-chip computer system is made up of several followi ng parts: ( 1) One microprocessor of 8 (CPU). ( 2) At slice data memory RAM (128B/256B),it use not depositti ng not can read ing /data that write, such as result not middle of operati on, final result and data wan ted to show, etc. ( 3) Procedure memoryROM/EPRC(4KB/8KB ), is used to preserve the procedure , some in itial data and form in slice. But does not take ROM/EPROM within some on e-chip computers, such as 8031 , 8032, 80C ,etc.. ( 4) Four 8 run side by side I/O in terface P0 four P3, each mouth can use as introduction , may use as export ing too. ( 5) Two timer / coun ter, each timer / coun ter may set up and count in the way, used to count to the exter nal in cide nt, can set up into a timi ng way too, and can accord ing to count or result of timing realize the control of the computer. (6) Five cut off cutting off the control system of the source .
The Introduction of AT89C51 Description The AT89C51 is a low-power, high-performance CMOS 8-bit microcomputer with 4K bytes of Flash programmable and erasable read only memory (PEROM). The device is manufactured using Atmel’s high-density nonvolatile memory technology and is compatible with the industry-standard MCS-51 instruction set. The on-chip Flash allows the program memory to be reprogrammed in-system or by a conventional nonvolatile memory programmer. By combining a versatile 8-bit CPU with Flash on a monolithic chip, the Atmel AT89C51 is a powerful microcomputer which provides a highly-flexible and cost-effective solution to many embedded control applications. Function characteristic The AT89C51 provides the following standard features: 4K bytes of Flash, 128 bytes of RAM, 32 I/O lines, two 16-bit timer/counters, one 5 vector two-level interrupt architecture, a full duplex serial port, one-chip oscillator and clock circuitry. In addition, the AT89C51 is designed with static logic for operation down to zero frequency and supports two software selectable power saving modes. The Idle Mode stops the CPU while allowing the RAM, timer/counters, serial port and interrupt system to continue functioning. The Power-down Mode saves the RAM contents but freezes the oscillator disabling all other chip functions until the next hardware reset. Pin Description VCC:Supply voltage. GND:Ground.
XX大学 本科毕业设计(论文)文献综述 课题名称: 学院(系): 年级专业: 学生姓名: 指导教师: 完成日期:
一、课题国内外现状 当今社会,应用单片机的产品已经渗透到我们生活的各个领域,几乎很难找到哪个领域没有单片机的足迹。现在,这种单片机的使用领域已十分广泛,如智能仪表、实时工控、通讯设备、导航系统、家用电器等,这些都离不开单片机。因此,单片机的学习、开发与应用将造就一批计算机应用与智能化控制的工程师和科学家。科技越发达,智能化的东西就越多。学习单片机是社会发展的必然需求,也是大学期间的必修课。 在国内单片机学习呈上升趋势,但是很多人学习时没有头绪,不知道从何下手。面对种类繁多的各类开发板,仿真器,让初学者无所事从,不但多花钱还多走不少弯路,学生学习单片机没有大的资金投入,能够做到少花钱多办事才是最好的。 Intel8051系列是我们在大学课堂中学习的。因此本课题围绕8051系列单片机设计,从电路图绘制,PCB板设计,硬件焊接,程序设计,在线仿真到各项功能实现,目的在于让学生将课堂上学来的理论知识与实践相结合,提高对单片机的认识,学习专业软件的操作,熟悉制作过程,掌握一门技能,加强专业知识的掌握。也增加学生的实践经历,为学生就业提供一个可选方向,拓展就业渠道。 二、研究主要成果 在目前的国内外市场中,主要单片机学习教学电路中,仿真器与开发板是分开的,且仿真器造价高,使用中仿真头易损坏。开发板种类多,不系统,应用中两者接合投资太高,学校投入太大。因仿真器与学习板是分开的,学生学习东西也少,板子做完后,学生只能留有学习板,想在课余再学习,终究因没有仿真器而受限止,实用性小,不能达到预期目的。 三、发展趋势 现在可以说单片机是百花齐放,百家争鸣的时期,世界上各大芯片制造公司都推出了自己的单片机,从8位、16位到32位,数不胜数,应有尽有,有与主流C51系列兼容的,也有不兼容的,但它们各具特色,互成互补,为单片机的应用提供广阔的天地。 微型单片化现在常规的单片机普遍都是将中央处理器(CPU)、随机存取数据存储(RAM)、只读程序存储器(ROM)、并行和串行通信接口,中断系统、定时电路、时钟电路集成在一块单一的芯片上,增强型的单片机集成了如A/D转换器、PMW(脉宽调制电路)、WDT(看门狗)、有些单片机将LCD(液晶)驱动电路都集成在单一的芯片上,这样单片机包含的单元电路就更多,功能就越强大。甚至单片
外文文献一单片机简介 单片机是一种集成在电路芯片,是采用超大规模集成电路技术把具有数据处理能力的中央处理器CPU随机存储器RAM、只读存储器ROM、多种I/O口和中断系统、定时器/计时器等功能(可能还包括显示驱动电路、脉宽调制电路、模拟多路转换器、A/D转换器等电路)集成到一块硅片上构成的一个小而完善的计算机系统。单片机也被称为微控制器(Microcontroller),是因为它最早被用在工业控制领域。单片机由芯片内仅有CPU的专用处理器发展而来。最早的设计理念是通过将大量外围设备和CPU集成在一个芯片中,使计算机系统更小,更容易集成进复杂的而对体积要求严格的控制设备当中。INTEL的Z80是最早按照这种思想设计出的处理器,从此以后,单片机和专用处理器的发展便分道扬镳。 二、单片机的发展趋势 现在可以说单片机是百花齐放,百家争鸣的时期,世界上各大芯片制造公司都推出了自己的单片机,从8位、16位到32位,数不胜数,应有尽有,有与主流C51系列兼容的,也有不兼容的,但它们各具特色,互成互补,为单片机的应用提供广阔的天地。 纵观单片机的发展过程,可以预示单片机的发展趋势,大致有: 1.低功耗CMOS MCS-51系列的8031推出时的功耗达630mW,而现在的单片机普遍都在100mW左右,随着对单片机功耗要求越来越低,现在的各个单片机制造商基本都采用了CMOS(互补金属氧化物半导体工艺)。象80C51就采用了HMOS(即高密度金属氧化物半导体工艺)和CHMOS(互补高密度金属氧化物半导体工艺)。CMOS虽然功耗较低,但由于其物理特征决定其工作速度不够高,而CHMOS则具备了高速和低功耗的特点,这些特征,更适合于在要求低功耗象电池供电的应用场合。所以这种工艺将是今后一段时期单片机发展的主要途径。 2.微型单片化 现在常规的单片机普遍都是将中央处理器(CPU)、随机存取数据存储(RAM)、只读程序存储器(ROM)、并行和串行通信接口,中断系统、定时电路、时钟电路集成在一块单一的芯片上,增强型的单片机集成了如A/D转换器、PMW(脉宽调制电路)、WDT(看门狗)、有些单片机将LCD(液晶)驱动电路都集成在单一的芯片上,这样 单片机包含的单元电路就更多,功能就越强大。甚至单片机厂商还可以根据用户的要求量身定做,制造出具有. 自己特色的单片机芯片。此外,现在的产品普遍要求体积小、重量轻,这就要求单片机除了功能强和功耗低外,还要求其体积要小。现在的许多单片机都具有多种封装形式,其中SMD(表面封装)越来越受欢迎,使得由单片机构成的系统正朝微型化方向发展。 3.主流与多品种共存 现在虽然单片机的品种繁多,各具特色,但仍以80C51为核心的单片机占主流,兼容其结构和指令系统的有PHILIPS公司的产品,ATMEL公司的产品和中国台湾
基于单片机的大棚温湿度控制系统设计 发布: 2011-9-1 | 作者: —— | 来源:caiminghao| 查看: 530次| 用户关注: 摘要:针对研究蔬菜大棚智能温湿度控制,设计了一种基于计算机自动控制的智能蔬菜大棚温湿度控制系统。详细阐述了该系统的温湿度采集、温湿度显示、控制系统等系统软硬件的设计思想,以DS18B20和HM1500LF作为温湿度传感器,以AT89S52单片机为系统核心,最后利用DELPHI软件进行系统仿真。该研究设计的蔬菜大棚智能温湿度控制系统人机界面良好,操作简单方便,自动化程度高,造价低廉,具有良好的应用前景和推广价值。关键词:温度采 摘要:针对研究蔬菜大棚智能温湿度控制,设计了一种基于计算机自动控制的智能蔬菜大棚温湿度控制系统。详细阐述了该系统的温湿度采集、温湿度显示、控制系统等系统软硬件的设计思想,以DS18B20和HM1500LF作为温湿度传感器,以AT89S52单片机为系统核心,最后利用DELPHI软件进行系统仿真。该研究设计的蔬菜大棚智能温湿度控制系统人机界面良好,操作简单方便,自动化程度高,造价低廉,具有良好的应用前景和推广价值。 关键词:温度采集;湿度采集;LCD显示;单片机 0 引言 植物的生长都是在一定的环境中进行的,在生长过程中受到环境中各种因素的影响,其中影响最大的是温度和湿度。若昼夜的温度和湿度变化很大,其对植物生长极为不利。因此必须对温度和湿度进行监测和控制,使其适合植物的生长,以提高其产量和质量。 本系统就是针对大棚内温度、湿度,研究单片机控制的温室大棚自动控制,综合考虑系统的精度、效率以及经济性要求多方面因素之后,设计一种基于计算机自动控制的大棚温湿度控制系统。 本系统实现的蔬菜大棚温湿度控制系统的目标功能如下: (1)系统能对大棚环境温湿度进行采集和显示(现场观温、湿度,软件记录)。 (2)能通过上位机端远程设定蔬菜的生长期适宜温湿度。由主控机统一设置系统时间和温度湿度修正值。 (3)当大棚的环境温湿度参数超过设定的上下限值时控制相应的系统启动。 (4)可实时显示当前温度、时间、报警阈值等信息,并可查询各时间段的温湿度情况,并加以控制。 1 系统各组成模块
沈阳工程学院毕业设计(论文) 外文文献 一单片机简介 单片机是一种集成在电路芯片,是采用超大规模集成电路技术把具有数据处理能力的中央处理器CPU随机存储器RAM、只读存储器ROM、多种I/O口和中断系统、定时器/计时器等功能(可能还包括显示驱动电路、脉宽调制电路、模拟多路转换器、A/D转换器等电路)集成到一块硅片上构成的一个小而完善的计算机系统。 单片机也被称为微控制器(Microcontroller),是因为它最早被用在工业控制领域。单片机由芯片内仅有CPU的专用处理器发展而来。最早的设计理念是通过将大量外围设备和CPU集成在一个芯片中,使计算机系统更小,更容易集成进复杂的而对体积要求严格的控制设备当中。INTEL的Z80是最早按照这种思想设计出的处理器,从此以后,单片机和专用处理器的发展便分道扬镳。 二、单片机的发展趋势 现在可以说单片机是百花齐放,百家争鸣的时期,世界上各大芯片制造公司都推出了自己的单片机,从8位、16位到32位,数不胜数,应有尽有,有与主流C51系列兼容的,也有不兼容的,但它们各具特色,互成互补,为单片机的应用提供广阔的天地。 纵观单片机的发展过程,可以预示单片机的发展趋势,大致有: 1.低功耗CMOS MCS-51系列的8031推出时的功耗达630mW,而现在的单片机普遍都在100mW左右,随着对单片机功耗要求越来越低,现在的各个单片机制造商基本都采用了CMOS(互补金属氧化物半导体工艺)。象80C51就采用了HMOS(即高密度金属氧化物半导体工艺)和CHMOS(互补高密度金属氧化物半导体工艺)。CMOS虽然功耗较低,但由于其物理特征决定其工作速度不够高,而CHMOS则具备了高速和低功耗的特点,这些特征,更适合于在要求低功耗象电池供电的应用场合。所以这种工艺将是今后一段时期单片机发展的主要途径。 2.微型单片化 现在常规的单片机普遍都是将中央处理器(CPU)、随机存取数据存储(RAM)、只读程序存储器(ROM)、并行和串行通信接口,中断系统、定时电路、时钟电路集成在一块单一的芯片上,增强型的单片机集成了如A/D转换器、PMW(脉宽调制电路)、WDT(看门狗)、有些单片机将LCD(液晶)驱动电路都集成在单一的芯片上,这样单片机包含的单元电路就更多,功能就越强大。甚至单片机厂商还可以根据用户的要求量身定做,制造出具有自己特色的单片机芯片。此外,现在的产品普遍要求体积小、重量轻,这就要求单片机除了功能强和功耗低外,还要求其体积要小。现在的许多单片机都具有多种封装形式,其中SMD(表面封装)越来越受欢迎,使得由单片机构成的系统正朝微型化方向发
中文资料原文 单片机 单片机也被称为微控制器(Microcontroller Unit),常用英文字母的缩写MCU表示单片机,它最早是被用在工业控制领域。单片机由芯片内仅有CPU的专用处理器发展而来。最早的设计理念是通过将大量外围设备和CPU集成在一个芯片中,使计算机系统更小,更容易集成进复杂的而对体积要求严格的控制设备当中。INTEL的Z80是最早按照这种思想设计出的处理器,从此以后,单片机和专用处理器的发展便分道扬镳。 早期的单片机都是8位或4位的。其中最成功的是INTEL的8031,因为简单可靠而性能不错获得了很大的好评。此后在8031上发展出了MCS51系列单片机系统。基于这一系统的单片机系统直到现在还在广泛使用。随着工业控制领域要求的提高,开始出现了16位单片机,但因为性价比不理想并未得到很广泛的应用。90年代后随着消费电子产品大发展,单片机技术得到了巨大提高。随着INTEL i960系列特别是后来的ARM系列的广泛应用,32位单片机迅速取代16位单片机的高端地位,并且进入主流市场。而传统的8位单片机的性能也得到了飞速提高,处理能力比起80年代提高了数百倍。目前,高端的32位单片机主频已经超过300MHz,性能直追90年代中期的专用处理器,而普通的型号出厂价格跌落至1美元,最高端[1]的型号也只有10美元。当代单片机系统已经不再只在裸机环境下开发和使用,大量专用的嵌入式操作系统被广泛应用在全系列的单片机上。而在作为掌上电脑和手机核心处理的高端单片机甚至可以直接使用专用的Windows和Linux操作系统。 单片机比专用处理器更适合应用于嵌入式系统,因此它得到了最多的应用。事实上单片机是世界上数量最多的计算机。现代人类生活中所用的几乎每件电子和机械产品中都会集成有单片机。手机、电话、计算器、家用电器、电子玩具、掌上电脑以及鼠标等电脑配件中都配有1-2部单片机。而个人电脑中也会有为数不少的单片机在工作。汽车上一般配备40多部单片机,复杂的工业控制系统上甚至可能有数百台单片机在同时工作!单片机的数量不仅远超过PC机和其他计算的总和,甚至比人类的数量还要多。 单片机又称单片微控制器,它不是完成某一个逻辑功能的芯片,而是把一个计算机系统集成到一个芯片上。相当于一个微型的计算机,和计算机相比,单片机只缺少了I/O设备。概括的讲:一块芯片就成了一台计算机。它的体积小、质量轻、价格便宜、为学习、应用和开发提供了便利条件。同时,学习使用单片机是了解计算机原理与结构的最佳选择。
外文文献原稿和译文 原稿 Front side Copyright of this circuit belongs to smart kit electronics. In this page we will use this circuit to discuss for improvements and we will introduce some changes based on original schematic General Description This is an easy to build, but nevertheless very accurate and useful digital voltmeter. It has been designed as a panel meter and can be used in DC power supplies or anywhere else it is necessary to have an accurate indication of the voltage present. The circuit employs the ADC (Analogue to Digital Converter) I.C. CL7107 made by INTERSIL. This IC incorporates in a 40 pin case all the circuitry necessary to convert an analogue signal to digital and can drive a series of four seven segment LED displays directly. The circuits built into the IC are an analogue to digital converter, a comparator, a clock, a decoder and a seven segment LED display driver. The circuit as it is described here can display any DC voltage in the range of 0-1999 Volts. Technical Specifications - Characteristics Supply Voltage: ............. +/- 5 V (Symmetrical) Power requirements: ..... 200 mA (maximum) Measuring range: .......... +/- 0-1,999 VDC in four ranges Accuracy: ....................... 0.1 % FEATURES Small size Easy construction
AT89C51的概况 一 AT89C51应用 单片机广泛应用于商业:诸如调制解调器,电动机控制系统,空调控制系统,汽车发动机和其他一些领域。这些单片机的高速处理速度和增强型外围设备集合使得它们适合于这种高速事件应用场合。然而,这些关键应用领域也要求这些单片机高度可靠。健壮的测试环境和用于验证这些无论在元部件层次还是系统级别的单片机的合适的工具环境保证了高可靠性和低市场风险。Intel 平台工程部门开发了一种面向对象的用于验证它的AT89C51 汽车单片机多线性测试环境。这种环境的目标不仅是为AT89C51 汽车单片机提供一种健壮测试环境,而且开发一种能够容易扩展并重复用来验证其他几种将来的单片机。开发的这种环境连接了AT89C51。本文讨论了这种测试环境的设计和原理,它的和各种硬件、软件环境部件的交互性,以及如何使用AT89C51。 1.1 介绍 8 位AT89C51 CHMOS 工艺单片机被设计用于处理高速计算和快速输入/输出。MCS51 单片机典型的应用是高速事件控制系统。商业应用包括调制解调器,电动机控制系统,打印机,影印机,空调控制系统,磁盘驱动器和医疗设备。汽车工业把MCS51 单片机用于发动机控制系统,悬挂系统和反锁制动系统。AT89C51 尤其很好适用于得益于它的处理速度和增强型片上外围功能集,诸如:汽车动力控制,车辆动态悬挂,反锁制动和稳定性控制应用。由于这些决定性应用,市场需要一种可靠的具有低干扰潜伏响应的费用-效能控制器,服务大量时间和事件驱动的在实时应用需要的集成外围的能力,具有在单一程序包中高出平均处理功率的中央处理器。拥有操作不可预测的设备的经济和法律风险是很高的。一旦进入市场,尤其任务决定性应用诸如自动驾驶仪或反锁制动系统,错误将是财力上所禁止的。重新设计的费用可以高达500K 美元,如果产品族享有同样内核或外围设计缺陷的话,费用会更高。另外,部件的替代品领域是极其昂贵的,因为设备要用来把模块典型地焊接成一个总体的价值比各个部件高几倍。为了缓和这些问题,在最坏的环境和电压条件下对这些单片机进行无论在部件级别还是系统级别上的综合测试是必需的。Intel Chandler 平台工程组提供了各种单片机和处理器的系统验证。这种系统的验证处理可以被分解为三个主要部分。系统的类型和应用需求决定了能够在设备上执行的测试类型。 1.2 AT89C51提供以下标准功能:
SCM is an integrated circuit chip, is the use of large scale integrated circuit technology to a data processing capability of CPU CPU random access memory RAM, read-only memory ROM, a variety of I / O port and interrupt system, timers / timer functions (which may also include display driver circuitry, pulse width modulation circuit, analog multiplexer, A / D converter circuit) integrated into a silicon constitute a small and complete computer systems. SCM is also known as micro-controller (Microcontroller), because it is the first to be used in industrial control. Only a single chip by the CPU chip developed from a dedicated processor. The first design is by a large number of peripherals and CPU on a chip in the computer system, smaller, more easily integrated into a complex and demanding on the volume control device which. The Z80 INTEL is the first designed in accordance with this idea processor, then on the development of microcontroller and dedicated processors will be parting ways. Are 8-bit microcontroller early or 4 bits. One of the most successful is the INTEL 8031, for a simple, reliable and good performance was a lot of praise. Then developed in 8031 out of MCS51 MCU Systems. SCM systems based on this system until now is still widely used. With the increased requirements of industrial control field, began a 16-bit microcontroller, but not ideal because the cost has not been very widely used. After 90 years with the great development of consumer electronics, microcontroller technology has been a huge increase. With INTEL i960 series, especially the later series of widely used ARM, 32-bit microcontroller quickly replace high-end 16-bit MCU status and enter the mainstream market. The traditional 8-bit microcontroller performance have been the rapid increase capacity increase compared to 80 the number of times. Currently, high-end 32-bit microcontroller clocked over 300MHz, the performance catching the mid-90s dedicated processor, while the average model prices fall to one U.S. dollar, the most high-end [1] model only 10 dollars. Modern SCM systems are no longer only in the development and use of bare metal environment, a large number of proprietary embedded operating system is widely used in the full range of SCM. The handheld computers and cell phones as the core processing of high-end microcontroller can even use a dedicated Windows and Linux operating systems. SCM is more suitable than the specific processor used in embedded systems, so it was up to the application. In fact the number of SCM is the world's largest computer. Modern human life used in almost every piece of electronic and mechanical products will be integrated single chip. Phone, telephone, calculator, home appliances, electronic toys, handheld computers and computer accessories such as a mouse with a 1-2 in both the Department of SCM. Personal computer will have a large number of SCM in the work. General car with more than 40 microcontroller, a complex industrial control systems may even hundreds of single chip at the same time work! SCM is not only far exceeds the number of PC and other computing the sum, or even more than the number of human beings. Single chip, also known as single-chip microcontroller, it is not complete a certain logic chips, but to a computer system integrated into a chip. Equivalent to a
广东工业大学 本科毕业设计(论文) 外文参考文献译文及原文 系部 专业自动化 年级 2006级 班级名称 学号 学生姓名 指导教师 2009年6月 目录 外文文献译文 (1) 1.单片机定义 (1) 2.单片机介绍 (2)
3.单片机历史 (3) 4.单片机的应用领域 (4) 5.at89c52单片机介绍 (6) 外文文献原文 (8) 1. The definition of a single-chip (8) 2. single-chip introduced (9) 3. single-chip history (11) 4. single-chip applications (12) 5.at89c52 chip explains (14)
外文文献译文 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。尽管他的大部分功能集成在一块小芯片上,但是它具有一个完整计算机所需要的大部分部件:CPU、内存、内部和外部总线系统,目前大部分还会具有外存。同时集成诸如通讯接口、定时器,实时时钟等外围设备。而现在最强大的单片机系统甚至可以将声音、图像、网络、复杂的输入输出系统集成在一块芯片上。 单片机也被称为微控制器(Microcontroller),是因为它最早被用在工业控制领域。单片机由芯片内仅有CPU的专用处理器发展而来。最早的设计理念是通过将大量外围设备和CPU集成在一个芯片中,使计算机系统更小,更容易集成进复杂的而对体积要求严格的控制设备当中。INTEL的Z80是最早按照这种思想设计出的处理器,从此以后,单片机和专用处理器的发展便分道扬镳。 早期的单片机都是8位或4位的。其中最成功的是INTEL的8031,因为简单可靠而性能不错获得了很大的好评。此后在8031上发展出了MCS51系列单片机系统。基于这一系统的单片机系统直到现在还在广泛使用。随着工业控制领域要求的提高,开始出现了16位单片机,但因为性价比不理想并未得到很广泛的应用。90年代后随着消费电子产品大发展,单片机技术得到了巨大的提高。随着INTEL i960系列特别是后来的ARM系列的广泛应用,32位单片机迅速取代16位单片机的高端地位,并且进入主流市场。而传统的8位单片机的性能也得到了飞速提高,处理能力比起80年代提高了数百倍。目前,高端的32位单片机主频已经超过300MHz,性能直追90年代中期的专用处理器,而普通的型号出厂价格跌落至1美元,最高端的型号也只有10美元。当代单片机系统已经不再只在裸机环境下开发和使用,大量专用的嵌入式操作系统被广泛应用在全系列的单片机上。而在作为掌上电脑和手机核心处理的高端单片机甚至可以直接使用专用的Windows和Linux操作系统。 单片机比专用处理器更适合应用于嵌入式系统,因此它得到了最多的应用。
外文文献 一单片机简介 单片机是一种集成在电路芯片,是采用超大规模集成电路技术把具有数据处理能力的中央处理器CPU随机存储器RAM、只读存储器ROM、多种I/O口和中断系统、定时器/计时器等功能(可能还包括显示驱动电路、脉宽调制电路、模拟多路转换器、A/D转换器等电路)集成到一块硅片上构成的一个小而完善的计算机系统。 单片机也被称为微控制器(Microcontroller),是因为它最早被用在工业控制领域。单片机由芯片内仅有CPU的专用处理器发展而来。最早的设计理念是通过将大量外围设备和CPU集成在一个芯片中,使计算机系统更小,更容易集成进复杂的而对体积要求严格的控制设备当中。INTEL的Z80是最早按照这种思想设计出的处理器,从此以后,单片机和专用处理器的发展便分道扬镳。 二、单片机的发展趋势 现在可以说单片机是百花齐放,百家争鸣的时期,世界上各大芯片制造公司都推出了自己的单片机,从8位、16位到32位,数不胜数,应有尽有,有与主流C51系列兼容的,也有不兼容的,但它们各具特色,互成互补,为单片机的应用提供广阔的天地。 纵观单片机的发展过程,可以预示单片机的发展趋势,大致有: 1.低功耗CMOS MCS-51系列的8031推出时的功耗达630mW,而现在的单片机普遍都在100mW左右,随着对单片机功耗要求越来越低,现在的各个单片机制造商基本都采用了CMOS(互补金属氧化物半导体工艺)。象80C51就采用了HMOS(即高密度金属氧化物半导体工艺)和CHMOS(互补高密度金属氧化物半导体工艺)。CMOS虽然功耗较低,但由于其物理特征决定其工作速度不够高,而CHMOS则具备了高速和低功耗的特点,这些特征,更适合于在要求低功耗象电池供电的应用场合。所以这种工艺将是今后一段时期单片机发展的主要途径。 2.微型单片化 现在常规的单片机普遍都是将中央处理器(CPU)、随机存取数据存储(RAM)、只读程序存储器(ROM)、并行和串行通信接口,中断系统、定时电路、时钟电路集成在一块单一的芯片上,增强型的单片机集成了如A/D转换器、PMW(脉宽调制电路)、WDT(看门狗)、有些单片机将LCD(液晶)驱动电路都集成在单一的芯片上,这样单片机包含的单元电路就更多,功能就越强大。甚至单片机厂商还可以根据用户的要求量身定做,制造出具有自己特色的单片机芯片。此外,现在的产品普遍要求体积小、重量轻,这就要求单片机除了功能强和功耗低外,还要求其体积要小。现在的许多单片机都具有多种封装形式,其中SMD(表面封装)越来越受欢迎,使得由单片机构成的系统正朝微型化方向发