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What is data acquisition system?
You can think of a data acquisitionsystem as a collection of software andhardware that connects you to the
physical world.
A typical data acquisition systemconsists of these components.
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Data acquisition hardware
At the heart of any data acquisition system lies thedata acquisition hardware. The main function ofthis hardware is to convert analog signals to digitalsignals, and to convert digital signals to analogsignals.
Sensors and actuators (transducers)
Sensors and actuators can both be transducers. A
transducer is a device that converts input energyof one form into output energy of another form.
For example, a microphone is a sensor thatconverts sound energy (in the form of pressure)
into electrical energy, while a loudspeaker is anactuator that converts electrical ener into sound
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4/22/12Signal conditioning hardwareSensor signals are often incompatible with dataacquisition hardware. To overcome this incompatibility, the signal must be
conditioned. For example, you might need tocondition an input signal by amplifying it or byremoving unwanted frequency components. Outputsignals might need conditioning as well.
computerThe computer provides a processor, a system
clock, a bus to transfer data, and memory and diskspace to store data.Software
Data acquisition software allows you to exchangeinformation between the computer and the hardware. For example, typical software allows you to configurethe sampling rate of your board, and acquire a
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4/22/12The data acquisition components, and theirrelationship to each other, are shown below.
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The figure depicts the two important features of a dataacquisition system:Signals are input to a sensor, conditioned, converted intobits that a computer can read, and analyzed to extractmeaningful information.For example, sound level data is acquired from a
microphone, amplified, digitized by a sound card, andstored in MATLAB workspace for subsequent analysis offrequency content.
Data from a computer is converted into an analog signal
and output to an actuator.For example, a vector of data in MATLAB workspace isconverted to an analog signal by a sound card and outputto a loudspeaker.
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4/22/12Data Acquisition HardwareData acquisition hardware is either internal andinstalled directly into an expansion slot inside yourcomputer, or external and connected to your
computer through an external cable, which is typicallya USB cable.
At the simplest level, data acquisition hardware is
characterized by the subsystems it possesses.
A subsystem is a component of your data acquisitionhardware that performs a specialized task.
Common subsystems includeAnalog inputAnalog outputDigital input/outputCounter/timer
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4/22/12Hardware devices that consist of multiplesubsystems, such as the one depicted below, arecalled multifunction boards.
Analog Input SubsystemsAnalog input subsystems convert real-world analog input
signals from a sensor into bits that can be read by yourcomputer. Perhaps the most important of all the subsystemscommonly available, they are typically multichanneldevices offering 12 or 16 bits of resolution.
Analog input subsystems are also referred to as AI
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Analog Output Subsystems
Analog output subsystems convert digital data stored onyour computer to a real-world analog signal.
These subsystems perform the inverse conversion ofanalog input subsystems.
Typical acquisition boards offer two output channelswith 12 bits of resolution, with special hardware available
to support multiple channel analog output operations.
Analog output subsystems are also referred to as AOsubsystems, D/A converters, or DACs.
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4/22/12Digital Input/Output Subsystems
Digital input/output (DIO) subsystems are designed toinput and output digital values (logic levels) to and fromhardware.
These values are typically handled either as single bits orlines, or as aport, which typically consists of eight lines.
While most popular data acquisition cards include somedigital I/O capability, it is usually limited to simpleoperations, and specialdedicated hardware is often necessary for performingadvanced digital I/O operations.
Counter/Timer Subsystems
Counter/timer (C/T) subsystems are used for eventcountin fre uenc and eriod measurement and ulse
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4/22/12Sensors
A sensor converts the physical phenomena of interestinto a signal that is input into your data acquisition
hardware.
There are two main types of sensors based on theoutput they produce: digital sensors and analog sensors.
Digital sensors produce an output signal that is a digitalrepresentation of the input signal, and has discretevalues of magnitude measured at discrete times.
A digital sensor must output logic levels that arecompatible with the digital receiver.Some standard logic levels include transistor-transistorlogic (TTL) and emitter-coupled logic (ECL). Examples ofdigital sensors include switches and position encoders.
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4/22/12Analog sensors
Analog sensors produce an output signal that isdirectly proportional to the input signal, and is
continuous in both magnitude and in time.
Most physical variables such as temperature,pressure, and acceleration are continuous in natureand are readily measured with an analog sensor.
For example, the temperature of an automobilecooling system and the acceleration produced by achild on a swing all vary continuously.
The sensor you use depends on the phenomena youare measuring. Some common analog sensors and thephysical variables they measure are listed below.
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Sensor Physical VariableAccelerometer Acceleration
Microphone Pressure
Pressure gauge Pressure
Resistive temperature device
(RTD)
Temperature
Strain gauge Force
Thermocouple Temperature
Common AnalogSensors
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When choosing the best analog sensor to use, you mustmatch the characteristics of the physical variable you aremeasuring with the characteristics of the sensor.The two most important sensor characteristics are:
The sensor output
The sensor bandwidth
Sensor OutputThe output from a sensor can be an analog signal or adigital signal, and the output variable is usually a voltagealthough some sensors output current.
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Sensor Bandwidth
The bandwidth is given by the range of frequenciespresent in the signal being measured.
You can also think of bandwidth as being related to the
rate of change of the signal.
A slowly varying signal has a low bandwidth, while arapidly varying signal has a high bandwidth.
To properly measure the physical phenomena ofinterest, the sensor bandwidth must be compatible withthe measurement bandwidth.
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You might want to use sensors with the widestpossible bandwidth when making any physicalmeasurement.
This is the one way to ensure that the basicmeasurement system is capable of respondinglinearly over the full range of interest.
However, the wider the bandwidth of the sensor,
the more you must be concerned with eliminatingsensor response to unwanted frequencycomponents.
i l di i i
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4/22/12Signal Conditioning
Sensor signals are often incompatible with data
acquisition hardware.To overcome this incompatibility, the sensor signal mustbe conditioned.The type of signal conditioning required depends on thesensor you are using.
For example, a signal might have a small amplitudeand require amplification, or it might contain unwantedfrequency components and require filtering.Common ways to condition signals include
AmplificationFilteringElectrical isolationMultiplexing
Excitation source
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Amplification
Low-level less than around 100 millivolts usuallyneed to be amplified.
High-level signals might also require amplificationdepending on the input range of the analog input
subsystem.
For example, the output signal from a thermocouple issmall and must be amplified before it is digitized.
Signal amplification allows you to reduce noise and tomake use of the full range of your hardware therebyincreasing the resolution of the measurement.
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Filtering
Filtering removes unwanted noise from the signal ofinterest.
A noise filter is used on slowly varying signals such
as temperature to attenuate higher frequency signalsthat can reduce the accuracy of your measurement.
Rapidly varying signals such as vibration oftenrequire a different type of filter known as an
antialiasing filter.
An antialiasing filter removes undesirable higherfrequencies that might lead to erroneous
measurements.
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Electrical Isolation
If the signal of interest contains high-voltagetransients that could damage the computer, then thesensor signals should be electrically isolated from the
computer for safety purposes.
You can also use electrical isolation to make sure thatthe readings from the data acquisition hardware arenot affected by differences in ground potentials.
M lti l i
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4/22/12Multiplexing
A common technique for measuring several signals
with a single measuring device is multiplexing.Signal conditioning devices for analog signals oftenprovide multiplexing for use with slowly changingsignals such as temperature.This is in addition to any built-in multiplexing on the
DAQ board. The A/D converter samples one channel,switches to the next channel and samples it, switchesto the next channel, and so on.Because the same A/D converter is sampling many
channels, the effective sampling rate of eachindividual channel is inversely proportional to thenumber of channels sampled.You must take care when using multiplexers so thatthe switched signal has sufficient time to settle. Refer
to Noise for more information about settling time.
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Excitation Source
Some sensors require an excitation source tooperate.
For example, strain gauges, and resistive
temperature devices (RTDs) require externalvoltage or current excitation.
Signal conditioning modules for these sensorsusually provide the necessary excitation.
RTD measurements are usually made with acurrent source that converts the variation inresistance to a measurable voltage.
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4/22/12The ComputerThe computer provides a processor, a system clock, abus to transfer data, and memory and disk space to storedata.
The processor controls how fast data is accepted by theconverter. The system clock provides time informationabout the acquired data.
Data is transferred from the hardware to system memory viadynamic memory access (DMA) or interrupts.
DMA is hardware controlled and therefore extremely fast.
Interrupts might be slow because of the latency time betweenwhen a board requests interrupt servicing and when the computerresponds.
The maximum acquisition rate is also determined by thecomputer's bus architecture.
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4/22/12Software
Regardless of the hardware you are using, you must
send information to the hardware and receiveinformation from the hardware. You send configuration information to the hardwaresuch as the sampling rate, and receive informationfrom the hardware such as data, status messages,
and error messages.You might also need to supply the hardware withinformation so that you can integrate it with otherhardware and with computer resources.
This information exchange is accomplished withsoftware.There are two kinds of software:
Driver software
Application software
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What is data logging?
Data logging and recording is a commonmeasurement application.
In its most basic form, data logging is the measuringand recording of physical or electrical parametersover a period of time.
The data can be temperature, strain, displacement,flow, pressure, voltage, current, resistance, power,and many other parameters.
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A wide range of products can be categorized as data
loggers, from basic devices that perform a singlemeasurement to more complex devices that offeranalysis functions and integrated displays.
Many applications are more involved than justacquiring and recording signals, sometimes involving acombination of online analysis, offline analysis, display,report generation, and data sharing.
Moreover, applications are beginning to require theacquisition and storage of other types of data, such asrecording sound and video in conjunction with theother parameters measured during an automobile
crash test.
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Figure 1. Data loggers can be both PC-based or stand-alone devices.
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Data logging is used in a broad spectrum ofapplications. Chemists record data such astemperature, pH, and pressure when performingexperiments in a lab.
Design engineers log performance parameters suchas vibration, temperature, and battery level to
evaluate product designs.
Civil engineers record strain and load on bridges overtime to evaluate safety.
Geologists use data logging to determine mineralformations when drilling for oil.
The list of applications for data logging goes on and
on, but all of these applications have similar common
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How does data logger works?
A data logger works with sensors toconvert physical phenomena andstimuli into electronic signals such as
voltage or current. These electronic signals are then
converted or digitized into binary data.
The binary data is then easily analyzedby software and stored on a PC harddrive or on other storage media such
as memory cards and CDs.
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Figure 2. How does a datalogger work?
A few components that every data logger must haveinclude:
Hardware to digitize what you are logging, includingsensors, signal conditioning, and analog-to-digitalconversion hardwareLong-term data storage, typically onboard memory
or a PC -
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Follow these steps when using a data logger:
Connect sensors like thermocouples, resistance
temperature detectors (RTDs), thermistors, straingages, and accelerometers to the data logger
Use your data-logging software to configure your
data loggerConfigure parameters like sample rate, alarms, andstart or stop conditions for your data-logging taskwith your data-logging software
Run the data-logging task After your hardwaredigitizes the sensor measurements, analyze andstore your data for future use
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What can u do with data loggerbesides just log data?
The ability to take sensormeasurements and store the data forfuture use is, by definition, a
characteristic of a data logger.
However, a data-logging applicationrarely requires only data acquisitionand storage. Inevitably, you need theability to analyze and present the data
to determine results and make
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Figure 3. Data-LoggingApplication Elements
Acquire This step includes your sensors and data
logger hardware as well as the conversion of physicalphenomena into digital signals.
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Online Analysis This step includes any analysis youwould like to do before storing the data.
A common example of this is converting the voltagemeasurement to meaningful scientific units, such asdegrees Celsius.You can complete these complex calculations and datacompressions before logging the data.Controlling part of a system based on currentmeasurements for example, a kill switch is also partof online analysis.Every data-logging software application should
complete the conversion from binary to voltage and theconversion from voltage to scientific units.
Log This step refers to the storage of analyzed dataincluding any formatting required for the data files.
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Offline Analysis This step includes any analysisyou would like to do after storing the data.
A common example is looking for trends inhistorical data or data reduction.
Displaying, Sharing, Reporting This stepincludes the creation of any reports you need tomake to present your data.
However, note that the figure above shows you
can also present data straight from online analysis.
This represents the ability to monitor and view thedata as you acquire and analyze it in addition to
simply viewing historical data.
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