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子信息工程毕业论文(中英文对照)-数据仓库--正确选择数据采集系统.doc
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子信息工程毕业论文(中英文对照)-数据仓库--正确选择数据采集系统.doc
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Selecting the Right Data Acquisition System
Engineers often must monitor a handful of signals over extended periods of time, and then
graph and analyze the resulting data. The need to monitor, record and analyze data arises in
a wide range of applications, including the design-verification stage of product development,
environmental chamber monitoring, component inspection, benchtop testing and process
trouble-shooting.
This application note describes the various methods and devices you can use to acquire,
record and analyze data, from the simple pen-and-paper method to using today's
sophisticated data acquisition systems. It discusses the advantages and disadvantages of
each method and provides a list of questions that will guide you in selecting the approach that
best suits your needs.
Introduction
In geotechnical engineering, we sometime encounter some difficulties such as monitoring
instruments distributed in a large area, dangerous environment of working site that cause
some difficulty for easy access. In this case, operators may adopt remote control, by which a
large amount of measured data will be transmitted to a observation room where the data are
to be collected, stored and processed.
The automatic data acquisition control system is able to complete the tasks as regular
automatic data monitoring, acquisition and store, featuring high automation, large data store
capacity and reliable performance.
The system is composed of acquisition control system and display system, with the following
features:
1. No. of Channels: 32 ( can be increased or decreased according to user's real needs.)
2. Scanning duration: decided by user, fastest 32 points/second
3. Store capacity: 20G( may be increased or decreased)
4. Display: (a) Table of parameter (b) History tendency (c) Column graphics.
5. Function: real time monitoring control, warning
6. Overall dimension: 50cm×50cm×72cm
Data acquisition systems, as the name implies, are products and/or processes used to collect
information to document or analyze some phenomenon. In the simplest form, a technician
logging the temperature of an oven on a piece of paper is performing data acquisition. As
technology has progressed, this type of process has been simplified and made more accurate,
versatile, and reliable through electronic equipment. Equipment ranges from simple recorders
to sophisticated computer systems. Data acquisition products serve as a focal point in a
system, tying together a wide variety of products, such as sensors that indicate temperature,
flow, level, or pressure. Some common data acquistion terms are shown below:
Data acquisition technology has taken giant leaps forward over the last 30 to 40 years. For
example, 40 years ago, in a typical college lab, apparatus for tracking the temperature rise in
a crucible of sodiumtungsten- bronze consisted of a thermocouple, a bridge, a lookup table, a
pad of paper and a pencil.
Today's college students are much more likely to use an automated process and analyze the
data on a PC Today, numerous options are available for gathering data. The optimal choice
depends on several factors, including the complexity of the task, the speed and accuracy you
require, and the documentation you want. Data acquisition systems range from the simple to
the complex, with a range of performance and functionality.
Pencil and paper
The old pencil and paper approach is still viable for some situations, and it is inexpensive,
readily available, quick and easy to get started. All you need to do is hook up a digital
multimeter (DMM) and begin recording data by hand.
Unfortunately, this method is error-prone, tends to be slow and requires extensive manual
analysis. In addition, it works only for a single channel of data; while you can use multiple
DMMs, the system will quickly becomes bulky and awkward. Accuracy is dependent on the
transcriber's level of fastidiousness and you may need to scale input manually. For example,
if the DMM is not set up to handle temperature sensors, manual scaling will be required.
Taking these limitations into account, this is often an acceptable
method when you need to perform a quick experiment.
Strip chart recorder
Modern versions of the venerable strip chart recorder allow you to capture data from several
inputs. They provide a permanent paper record of the data, and because this data is in
graphical format, they allow you to easily spot trends. Once set up, most recorders have
sufficient internal intelligence to run unattended — without the aid of either an operator or a
computer. Drawbacks include a lack of flexibility and relatively low accuracy, which is often
constrained to a few percentage points. You can typically perceive only small changes in the
pen plots. While recorders perform well when monitoring a few channels over a long period of
time, their value can be limited. For example, they are unable to turn another device on or off.
Other concerns include pen and paper maintenance, paper supply and data storage, all of
which translate into paper overuse and waste. Still, recorders are fairly easy to set up and
operate, and offer a permanent record of the data for quick and simple analysis.
Scanning digital multimeter
Some benchtop DMMs offer an optional scanning capability. A slot in the rear of the
instrument accepts a scanner card that can multiplex between multiple inputs, with 8 to 10
channels of mux being fairly common. DMM accuracy and the functionality inherent in the
instrument's front panel are retained. Flexibility is limited in that it is not possible to expand
beyond the number of channels available in the expansion slot. An external PC usually
handles data acquisition and analysis.
PC plug-in cards
PC plug-in cards are single-board measurement systems that take advantage of the ISA or
PCI-bus expansion slots in a PC. They often have reading rates as high as 100,000 readings
per second. Counts of 8 to 16 channels are common, and acquired data is stored directly into
the computer, where it can then be analyzed. Because the card is essentially part of the
computer, it is easy to set up tests. PC cards also are relatively inexpensive, in part, because
they rely on the host PC to provide power, the mechanical enclosure and the user interface.
Data acquisition options
In the downside, PC plug-in cards often have only 12 bits of resolution, so you can't perceive
small variations with the input signal. Furthermore, the electrical environment inside a PC
tends to be noisy, with high-speed clocks and bus noise radiated throughout. Often, this
electrical interference limits the accuracy of the PC plug-in card to that of a handheld
DMM .These cards also measure a fairly limited range of dc voltage. To measure other input
signals, such as ac voltage, temperature or resistance, you may need some sort of external
signal conditioning. Additional concerns include problematic calibration and overall system
cost, especially if you need to purchase additional signal conditioning accessories or a PC to
accommodate the cards. Taking that into consideration, PC plug-in cards offer an attractive
approach to data acquisition if your requirements fall within the capabilities and limitations of
the card.
Data loggers
Data loggers are typically stand-alone instruments that, once they are setup, can measure,
record and display data without operator or computer intervention. They can handle multiple
inputs, in some instances up to 120 channels. Accuracy rivals that found in standalone bench
DMMs, with performance in the 22-bit, 0.004-percent accuracy range. Some data loggers
have the ability to scale measurements, check results against user-defined limits, and output
signals for control.
One advantage of using data loggers is their built-in signal conditioning. Most are able to
directly measure a number of different inputs without the need for additional signal
conditioning accessories. One channel could be monitoring a thermocouple, another a
resistive temperature device (RTD) and still another could be looking at voltage.
Thermocouple reference compensation for accurate temperature measurement is typically
built into the multiplexer cards. A data logger's built-in intelligence helps you set up the test
routine and specify the parameters of each channel. Once you have completed the setup,
data loggers can run as standalone devices, much like a recorder. They store data locally in
internal memory, which can accommodate 50,000 readings or more.
PC connectivity makes it easy to transfer data to your computer for in-depth analysis. Most
data loggers are designed for flexibility and simple configuration and operation, and many
provide the option of remote site operation via battery packs or other methods. Depending on
the A/D converter technique used, certain data loggers take readings at a relatively slow rate,
especially compared to many PC plug-in cards. Still, reading speeds of 250 readings/second
are not uncommon. Keep in mind that many of the phenomena being monitored are physical
in nature — such as temperature, pressure and flow — and change at a fairly slow rate.
Additionally, because of a data logger's superior measurement accuracy, multiple readings
and averaging are not necessary, as they often are in PC plug-in solutions.
Data acquisition front ends
Data acquisition front ends are often modular and are typically connected to a PC or controller.
They are used in automated test applications for gathering data and for controlling and routing
signals in other parts of the test setup. Front end performance can be very high, with speed
and accuracy rivaling the best standalone instruments. Data acquisition front ends are
implemented in a number of formats, including VXI versions, such as the Agilent E1419A
multifunction measurement and control VXI module, and proprietary card cages.. Although
front-end cost has been decreasing, these systems can be fairly expensive, and unless you
require the high performance they provide, you may find their price to be prohibitive. On the
plus side, they do offer considerable flexibility and measurement capability.
Data Logger Applications
A good, low-cost data logger with moderate channel count (20 - 60 channels) and a relatively
slow scan rate is more than sufficient for many of the applications engineers commonly face.
Some key applications include:
• Product characterization
• Thermal profiling of electronic products
• Environmental testing; environmental monitoring
• Component characterization
• Battery testing
• Building and computer room monitoring
• Process monitoring, evaluation and troubleshooting No single data acquisition system works
for all applications. Answering the following questions may help you decide which will best
meet your needs:
1. Does the system match my application?
What is the measurement resolution, accuracy and noise performance? How fast does it scan?
What transducers and measurement functions are supported? Is it upgradeable or
expandable to meet future needs? How portable is it? Can it operate as a standalone
instrument?
2. How much does it cost?
Is software included, or is it extra? Does it require signal conditioning add-ons? What is the
warranty period? How easy and inexpensive is it to calibrate?
3. How easy is it to use?
Can the specifications be understood? What is the user interface like? How difficult is it to
reconfigure for new applications? Can data be transferred easily to new applications? Which
application packages are supported?
Conclusion
Data acquisition can range from pencil, paper and a measuring device, to a highly
sophisticated system of hardware instrumentation and software analysis tools. The first step
for users contemplating the purchase of a data acquisition device or system is to determine
the tasks at hand and the desired output, and then select the type and scope of equipment
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