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Data Acquisition and Data Logging

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... simplest form could be to measure the length of a piece of string with a ruler ... Rate of measurements that need to be made. ... – PowerPoint PPT presentation

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Title: Data Acquisition and Data Logging


1
Data Acquisition and Data Logging
  • Some basics

2
What is data acquisition and data logging?
  • Data acquisition is simply the gathering of
    information about a system or process
  • Information may be gathered for various reasons
  • knowledge
  • research and development
  • systems or process monitoring
  • systems or process control
  • Data acquisition requires one or more transducers
    (sensors) to sense the system or process, and a
    signal measuring instrument

3
What is data acquisition and data logging?
  • Real Time Data Acquisition relates to data being
    acquired and used in the same time frame, such as
    when monitoring or controlling a system or
    process
  • Data Logging is when acquired data is stored or
    logged for later use or analysis. Involves some
    form of memory.

4
What is data acquisition and data logging?
  • Data acquisition and data logging is not a
    complex or mysterious science as viewed by some
  • Data acquisition in its simplest form could be to
    measure the length of a piece of string with a
    ruler
  • Data logging in its simplest form could be to
    write that measured length down on a sheet of
    paper

5
A data acquisition or data logging system
  • A data acquisition or data logging system
    generally includes the following components
  • sensors or transducers which provide the
    fundamental information of the parameters to be
    measured
  • a device to convert the primary signal from the
    sensors into a form compatible with information
    processing systems
  • a computer or other controller which supervises
    the overall system, and manages the generated
    data

6
Plan your task
  • Before you start
  • What am I trying to measure?
  • How am I going to measure?
  • How accurately do I want measure?
  • How often do I need to measure?
  • During
  • Calculations, Data reduction, Alarms
  • After
  • How am I going to recover my data?
  • What am I going to do with my data?
  • Post processing

7
Parameters to measure
  • There are many different parameters for which
    sensors or transducers are commonly available
  • temperature
  • pressure, force, mass, weight
  • velocity, acceleration, vibration
  • strain, stress, distortion, fatigue
  • flow, volume, level
  • length, width, depth, thickness, displacement
  • state, pulse, counter
  • composition, concentration

8
Parameters to measure
  • Selecting suitable sensors is often the most
    difficult task

9
Types of sensors
  • Sensors produce an electrical output that is
    proportional to the quantity of the parameter
    being sensed
  • Electrical output from sensors can be
  • Voltage, direct or alternating
  • Current, current loop
  • Resistance, conductance
  • Frequency
  • Binary states or pulses (counts)
  • Serial data - RS232, RS422, RS485, SDI-12
  • Parallel data - BCD, Gray Code, quadrature
    encoded

10
Characteristics of sensors
  • General characteristics to consider
  • Accuracy
  • Degree of agreement between the measured value
    and the true value
  • Linearity
  • How well the measured data points fit a straight
    line
  • Repeatability
  • The degree of variance of successive readings of
    a measured value.
  • Match the sensor characteristics to the parameter
    being measured

11
Support for sensors
  • Sensors often require support that must be
    provided by the data acquisition system or data
    logger
  • sensor excitation
  • signal conditioning
  • compensation for cable effects
  • management of references, zeros, etc
  • scaling of the electrical output to parameter
    units
  • Ability of data acquisition system or data logger
    to support sensors can determine the
    effectiveness of a project

12
Reading information from sensors
  • Many sensors produce an analog signal, such as
    voltage, current, resistance, frequency, etc.
  • Analog signals are measured by a process of
    Analog to Digital Conversion or ADC
  • Important characteristics of ADC are
  • accuracy
  • resolution
  • linearity
  • repeatability
  • speed
  • common mode range
  • electrical noise rejection

13
Resolution, accuracy, linearity, repeatability
  • These terms are often confused, however they have
    very different and important meaning
  • Apply to both the ADC and to sensors
  • Important to consider when matching sensors and
    data acquisition systems to requirements

14
Resolution, accuracy, linearity, repeatability
  • Resolution is the degree to which the ADC can
    determine that two readings are different.
  • usually expressed as a binary proportion of the
    measuring range
  • for example a 16 bit ADC resolves to 165535 of
    range, for a 1 Volt range this is 15.26 microvolt
  • small data loggers commonly have 12 bit
    resolution, larger systems have 16 bit resolution
    or greater
  • resolution is usually fixed, but may vary with
    sampling speed

15
Resolution, accuracy, linearity, repeatability
  • Accuracy is the degree to which the ADC can
    measure the true value of a signal.
  • usually expressed as full scale of measuring
    range
  • for example an accuracy of 0.1 for a 1 Volt
    measuring range is 1 millivolt
  • accuracy will often vary with operating
    conditions such as ambient temperature, signal
    type, environmental noise, etc.

16
Resolution, accuracy, linearity, repeatability
  • Linearity is the degree to which the relationship
    between the true value of the signal and the
    measured value of the signal remain constant over
    the measuring range.
  • usually expressed as full scale of measuring
    range
  • for example a linearity of 0.01 for a 1 Volt
    measuring range is 0.1 millivolt
  • linearity will often vary with operating
    conditions such as ambient temperature, signal
    type, environmental noise, etc.

17
Resolution, accuracy, linearity, repeatability
  • Repeatability is the degree to which the ADC will
    measure the same value for the same signal level
    on successive occasions.
  • usually expressed as full scale of measuring
    range
  • for example a repeatability of 0.01 for a 1 Volt
    measuring range is 0.1 millivolt
  • repeatability will often vary with operating
    conditions such as ambient temperature, signal
    type, environmental noise, etc.

18
Common mode range
  • Common mode range is a measure of the ability of
    the ADC to measure a signal separate from local
    ground

19
Electrical noise rejection
  • Noise rejection is the ability of the ADC to
    eliminate local environmental electrical noise
    from the measurements

20
Sampling Speed
  • Sampling speed is the number of readings per unit
    time of a single channel, or of a group of
    channels
  • Expressed as samples/second (Hz, KHz)
  • Varies from less than 1 Hz to 100s KHz for
    different data acquisition systems
  • May be variable within the same system

21
Sampling Speed
  • Appropriate sampling speed is dependent on many
    factors
  • what type of information is to be captured -
    short term events, long term trends, both?
  • when is information to be captured?
  • what is the level of importance of various
    information?
  • Aim to set a sampling speed to
  • maximize sensitivity of data.
  • minimize redundancy of data.
  • optimize generation of reports.
  • simplify archiving of data.

22
Number of channels
  • Most data acquisition systems have a single
    analog to digital converter, and many input
    channels
  • Input channels are selected for measurement by a
    switch or multiplexer (mux), which may be
    sequential or random. Switching may be by relay
    or solid state.
  • Only one channel can be measured at a time
  • Consideration must be given to sensor bounce
    when a sensor is selected for measurement

23
Data recovery and transfer
  • Data can be recovered from data acquisition
    systems and data loggers in various ways.
  • Serial comms interface via direct connect,
    modem, cell phone, radio, satellite
  • PCMCIA - modem, cell phone, LAN, memory card,
    USB memory device
  • Network port - Ethernet, field bus, proprietary,
    etc
  • Universal Serial Bus (USB)
  • Data can be transferred and published using
  • Local Ethernet network
  • Intranet - email, web pages
  • Internet - email, world wide web pages

24
Data processing and reporting
  • Collected data is analyzed and reported using any
    of
  • generic packages such as
  • ASCII text editors
  • Spreadsheets
  • Databases
  • general purpose data processing packages
  • general purpose SCADA packages
  • proprietary host software packages

25
Other functionality
  • In addition to the core functionality of data
    acquisition, modern data acquisition and data
    logging systems have other functionality
    including
  • real-time calculations, statistics, FFT, etc.
  • alarms testing for out of range conditions.
  • control feedback to the measured system or
    process.
  • a range of communications and memory options etc.

26
Form factor for dataacquisition systems
  • Data acquisition systems can be of a number of
    forms
  • Pocket loggers - small, battery powered, stand
    alone devices with simple functionality
  • Intelligent data loggers - stand alone devices
    with own intelligence, sophisticated data
    manipulation, alarms, backed up power supply,
    displays, etc. Accessed continuously or
    periodically by a PC.
  • Plug in cards - plugged into the ISA bus or USB
    port of a PC to provide basic data acquisition
    functionality. The PC provides power, control,
    data storage, etc.

27
Exercise
  • Write down the following
  • Types of sensors you will use.
  • The accuracy / repeatability required.
  • Sensor power requirements.
  • Sensor scaling.
  • Rate of measurements that need to be made.
  • The method of powering the logger, sensors and
    communications systems.
  • The memory requirements of the application.
  • The method of communicating with the logger.
  • The method of displaying, distributing and
    analysing the data collected.
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