【正文】 The Dynamic Data Acquisition System (DDAS) is designed to record time data with frequence up to 100 KHz. The JNL DDAS is based on a SUN SPARC10 VME bus puter with recording capacity of 30 dynamic channels. A VME array processing card is included for performing data analysis (primarily fast Fourier transforms) in conjunction with data acquisition. The JNL has a 28 microphone linear array for recording the fareld jet acoustics. Br uel amp。 大連交通大學(xué)信息工程學(xué)院 畢業(yè)設(shè)計 (論文 )外文翻譯 學(xué)生姓名 1111 專業(yè)班級 自動化 0111班 指導(dǎo)教師 1111 職 稱 11111 所在單位 電氣工程系 教研室 主任 完成日期 1111 年 4 月 13 日 大連 交通大學(xué)信息工程 學(xué)院 2021 屆本科生畢業(yè)設(shè)計（論文）外文翻譯 1 Date Acquisition Date acquisition systems are used to acquire process operating data and store it on secondary storage devices for later analysis. Many of the data acquisition systems acquire this data at very high speeds and very little puter time is left to carry out any necessary, or desirable, data manipulations or reduction. All the data are stored on secondary storage devices and manipulated subsequently to derive the variables of interest. It is very often necessary to design special purpose data acquisition systems and interfaces to acquire the high speed process data. This special purpose design can be an expensive proposition. Powerful mini and mainframe puters are used to bine the data acquisition with other functions such as parisons between the actual output and the desirable output values, and to then decide on the control action which must be taken to ensure that the output variables lie within preset limits. The puting power required will depend upon the type of process control system implemented .Software requirements for carrying out proportional, ratio or three term control of process variables are relatively trivial , and microputers can be used to implement such process control systems . It would not be possible to use many of the currently available microputers for the implementation of high speed adaptive control systems which require the use of suitable process models and considerable online manipulation of data. Microputer based data loggers are used to carry out intermediate functions such as data acquisition at paratively low speeds, simple mathematical manipulations of raw data and some forms of data reduction. The first generation of data loggers, without any programmable puting facilities, were used simply for slow speed data acquisition from up to one hundred channels. All the acquired data could be punched out on paper tape or printed for subsequent analysis. Such hardwired data loggers are being replaced by the new generation of data loggers which incorporate microputers and can be programmed by the user. They offer an extremely good method of collecting the process data, using standardized interfaces, and subsequently performing the necessary manipulations to provide the information of interest to the process operator. The data acquired can be analyzed to establish correlations, if any, between process variables and to develop mathematical models necessary for adaptive and optimal process control. The data acquisition function carried out by data loggers varies from one logging system to another. Simple data logging systems acquire data from a few channels while plex systems can receive data from hundreds, or even thousands, of input channels distributed 大連 交通大學(xué)信息工程 學(xué)院 2021 屆本科生畢業(yè)設(shè)計（論文）外文翻譯 2 around one or more processes. The rudimentary data loggers scan select number of channels, connected to sensors or transducers, in a sequential manner and the data are recorded in digital format. A data logger can be dedicated in the sense that it can only collect data from particular types of sensors and transducers. It is best to use a nondedicated data logger since any transducer or sensor can be connected to the use of appropriate signal conditioning modules. Microputer controlled data acquisition facilitates the scanning of a large number of sensors. The scanning rate depends upon the signal dynamics which means that some channels must be scanned at very high speeds in order to avoid aliasing errors while here is very little loss of information by scanning other cannels at slower speeds. In some data logging applications the faster channels require sampling at speeds of up to 100 times per second while slow channels can be sampled once every five minutes. The conventional hardwired, nonprogrammable data loggers sample all the channels in a sequential manner and the sampling frequency of all the channels must be the same. This procedure results in the accumulation of very large amounts of data, some of which is unnecessary, and also slows down the overall effective sampling frequency. Microputer based data loggers can be used to scan some fast channels at a higher frequency than other slow speed channels. The vast majority of the user programmable data loggers can be used to scan up to 1000 analog and 1000 digital input channels. A small number of data loggers, with a higher degree of sophistication, are suitable for acquiring data from up to 15,000 analog and digital channels. The data from digital channels can be in the form of TransistorTransistor Logic or contact closure signals. Analog data must be converted into digital format before it is recorded and requires the use of suitable analog to digital converters (ADC). The characteristics of the ADC will define the resolution that can be achieved and the rate at which the various channels can be sampled. An increase in the number of bits used in the ADC improves the resolution capability. Successive approximation ADC’s are faster than integrating ADC’s. Many microputer controlled data loggers include a facility to program the channel scanning rates. Typical scannin