Analog-Signal Data Acquisition in Industrial Automation

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Keywords: 4-20mA, 0-10V, +/-10V, 0-5V, +/-5V, multiranging adc, analog to digital, analog digital,
converters, programmable logic controllers, plc, overranging, fault
APPLICATION NOTE 270
Analog-Signal Data Acquisition in Industrial
Automation Systems
Aug 01, 2000
Abstract: Industrial control systems continue to employ standard analog signals for transmitting data
between the process and the control equipment. Robust, 4-to-20mA current-loop signals that are easily
transmitted over several thousand feet, ±5 and ±10V signals are also very common in industrial systems.
This application note showcases Maxim's integrated Data Acquisition System (DAS) solutions. Maxim's
DAS solutions save board space, power, and design time, while requiring minimal external components
to convert standard industrial analog signals.
Despite the availability of the digital field bus in several versions, industrial control systems continue to
employ standard analog signals for transmitting data between the process and the control equipment.
Process transmitters in a chemical plant, for example, convert low-level temperature and pressure
signals into robust, 4-to-20mA current-loop signals that are easily transmitted over several thousand feet.
Speed and position sensors for machine tools and automatic handlers in factory-automation
environments generate unipolar and bipolar voltage signals, which are typically 0V to 5V, 0V to 10V,
±5V, or ±10V. In addition, signals from the popular PT100 temperature-sensing element are often used
directly, without conversion, to a standard range such as 10V or 20mA. As an RTD (resistive thermal
device) made of platinum (Pt), the PT100 exhibits a resistance of 100Ω at 0°C. Its resistance versus
temperature characteristic is linear, and it offers a reasonably high level of output signal (>100mV when
driven with a 1mA current source).
The control function in a process environment is implemented by PLCs (programmable logic controllers),
PCSs (process control systems), or (more recently) by IPCs (industrial personal computers). Because
these devices are digital systems operating with process-specific software, all analog signals must be
converted to digital numbers before a computer can read them.
A/D conversion in a control system is performed by boards or boxes called "analog peripherals." They
connect to the CPU via the system's back-plane bus, or a field bus if mounted remotely (on a machine,
for example). In addition to digital circuits (for communication with the CPU), these peripheral units
include various precision-analog and mixed-signal components. Requirements for a larger number of
channels per board or for smaller packages (to mount on a machine) lead to shortages of space and
power that constitute a major challenge in designing analog peripherals. The following circuits suggest
signal-conditioning techniques and describe an approach for digitizing up to eight channels with a single
chip.
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Data-Acquisition System (DAS)
A state-of-the-art data-acquisition system (Figure 1) includes a multiplexer (mux) for switching between
input channels, a signal-conditioning circuit that provides gain and offset adjustment for different input
ranges, and an analog-to-digital converter (ADC) with voltage reference (VREF).
Figure 1. This diagram shows the basic components in a data-acquisition system.
Integrated DAS Solutions
By integrating the basic blocks of Figure 1, Maxim has produced a family of one-chip data-acquisition
systems that save board space, power, and design time. Requiring few external components (none in
some cases), these chips convert most of the standard signals currently in use. Each includes a 12-bit
ADC, multiplexer, and gain/offset correction, and features a serial or parallel digital interface that
connects easily to most microprocessors.
The following block diagram (Figure 2) is typical for this family of chips. Differences are mainly in the
digital section, which connects to the microprocessor. Each chip has six or eight single-ended analoginput channels that connect to the internal ADC through a fault-protected multiplexer. Any channel can
withstand input voltages up to 16.5V, and a fault on any channel does not affect conversions on any
other channel.
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Figure 2. The functions shown in Figure 1 are integrated in this chip.
Each channel can be programmed independently for one of the standard input ranges (0 to 5V, 0 to 10V,
±5V, or ±10V) while operating from a single 5V supply. Others have a similar gain structure but accept
different input ranges: unipolar or bipolar 2V or 4V, or unipolar or bipolar VREF or _VREF. The ability to
change the gain by a factor of two and offset the input by 100% (from -10V to +10V) extends the
dynamic range by 2 bits, producing a system with 14-bit dynamic range.
The internal ADC is a 12-bit successive-approximation type based on a capacitive DAC whose MSB
capacitor doubles as the hold capacitor in a track/hold circuit. Each device can operate with the internal
oscillator or with an external clock.
By using active-low WR pulses to start and stop an acquisition, MAX196-through-MAX199 devices in the
"external acquisition mode" can offer a relatively long acquisition time without slowing the conversion.
The device's short aperture delay and low aperture jitter (<50ps in the external clock/acquisition mode)
enable precise control of acquisition time. This feature is important for phase-sensitive applications such
as power-line control and AC-motor control. In addition, the chip's wideband input structure provides
small-signal bandwidths to 5MHz, which allows undersampling techniques in which input frequencies
exceed the Nyquist frequency.
Digital Interface
Applications that require high-speed measurements are best served with a parallel-data interface
(MAX196 through MAX199). These parts achieve throughputs of 100Ksps at 2MHz clock rates, which is
sufficient for most high-speed control loops. For low-speed applications, the available I²C-compatibleinterface versions save board space and simplify communications between the DAS and the
microcontroller. These parts have fast conversion times (10µs), but the serial interface limits their
throughput to 8kbps.
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The MAX197, for example, accepts 0V-to-10V, 0V-to-5V, ±5V, and ±10V inputs. Source impedance
driving these inputs is the user's main concern. When sampling, the ADC draws current pulses to charge
its T/H capacitor (the MSB capacitor of the capacitive DAC). Therefore, a fast-settling op amp with
sufficient slew rate is required to ensure sufficient voltage settling during the acquisition time.
MXL1013/MXL1014 op amps perform well for fast sampling rates. For slower op amps, the acquisition
time must be extended.
The differential inputs used in many automated systems are relatively insensitive to common-mode
interference. Sufficient in most cases is a simple differential amplifier circuit (Figure 3) whose input
resistance exceeds 1MΩ. (For much higher input impedance, use a standard 3-op-amp instrumentation
amplifier.) The output shown in Figure 3 is
VOUT = R2(V+ - V-)/R1.
For high common-mode rejection, make R1 = R3 and R2 = R4. The combination shown has a gain of
0.876, which enables the measurement of out-of-range signals by extending the ±10V input range
approximately 114%. This adjustment reduces resolution in the ±10V band to approximately 11.8 bits.
Figure 3. A simple differential amplifier provides high input impedance and a single-ended output.
20mA Current Loops
Current loops transmit small signals over large distances in noisy environments. The current is usually
generated by a process transmitter that converts a variable such as temperature or pressure to a DC
current in the range 0mA to 20mA or 4mA to 20mA. Then, passing the current through a shunt resistor
produces a proportional voltage drop that is easily digitized. Because the compliance voltage available
for driving the loop (including wire resistance) is seldom more than 15V to 18V, the resistor value is
limited to a few hundred ohms (Figure 4).
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Figure 4. Combining the amplifier shown in Figure 3 with a current-loop signal derived from a 220Ω
shunt resistor produces a convenient single-ended output.
This circuit has the same differential amplifier as the ±10V conditioning circuit, together with a 220Ω
shunt resistor, which drops 4.4V at 20mA or 5.5V at 25mA. The gain of the differential amplifier adjusts
to a maximum of 4.62V at the ADC input, so a DAS programmed for 0.5V inputs can digitize this signal
with a maximum resolution of 11.8 bits.
Because the MAX198/MAX199 and MAX128 have the smallest input ranges available in this family, and
therefore operate with a small shunt resistor and require no gain adjustment, they are better suited for
20mA measurements in systems that require no other high-level measurements (to ±10V). To adapt the
circuit shown in Figure 4 for operation with the MAX199, configure the MAX199 for its 0-to-2V input
range and change the 536kΩ resistors to 470kΩ. Use an 86Ω shunt resistor.
Sensor Adaptation
Thermocouples, strain gauges, and other popular sensors deliver low-level nonlinear signals that are
sensitive to EMI. Before sending this information to a control system, therefore, a 4-to-20mA transmitter
first linearizes and conditions the signal. For temperature-measurement applications that are less critical,
a resistive thermal device (RTD) can measure temperatures as high as 850°C over a great distance and
without expensive signal conditioning.
The most popular RTD is a standardized platinum temperature sensor called the PT100, which exhibits
100Ω resistance at 0°C and a linear temperature coefficient of 0.38Ω/°C. It also has a nonlinear
temperature coefficient that is much smaller, so the Ω/°C characteristic appears almost linear over a
narrow range. Unlike thermocouples, which deliver voltages that represent the difference between two
temperatures, the resistance of an RTD represents the absolute temperature of that resistance.
Measurement is accomplished by driving a current of 1mA to 2mA through the sensor and measuring the
voltage drop across it. Higher currents cause measurement error due to self-heating caused by higher
power dissipation within the sensor. An internal 4.096V reference simplifies the generation of excitation
current for the sensor(Figure 5).
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Figure 5. This circuit provides current to an RTD sensor and digitizes the resulting output.
To prevent wire resistance from affecting the measurement accuracy, four separate wires connect the
RTD to the differential amplifier. Because the sense wires connect to the amplifier's high impedance
inputs, they have very low current and virtually no voltage drop. The 4096mV reference and 3.3kΩ
feedback resistor sets the excitation current to approximately 4096mV/3.3kΩ = 1.24mA. Thus, driving the
ADC and current source with the same reference voltage produces a ratiometric measurement in which
reference drift does not influence the conversion result.
By configuring the MAX197 for an input range of 0V to 5V and setting the differential amplifier for a gain
of 10, you can measure resistance values up to 400Ω, which represents about 800°C. The µP can use a
look-up table to linearize the sensor signal. To calibrate the system, replace the RTD with two precision
resistors (100Ω for zero and 300Ω or higher for full span) and store the conversion results.
Rather than dedicating specific circuits for specific input ranges, use the following circuit (Figure 6) to
adapt the ADC input to any of the signal ranges described earlier. Choosing an input pin and ADC input
range (Table 1) selects the appropriate configuration.
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Figure 6. This universal-input circuit adapts the ADC to the signal range present on each input channel.
Table 1. Input Connections for Figure 6
INPUT CONNECT-->
1 2 3 4 5
ADC Range
±10V plus overrange
In- In+ ±10V
0mA- or 4mA-to-20mA, plus overrange In-In-In+ 0V to 5V
RTD
Sns- Sns+ 0V to 5V
For RTD: Sns- and Sns+ are sense connections on the four-wire configuration. Connect the "source"
pins to IS1 and IS2.
A version of this article appeared in the February 9, 1999, issue of Control Engineering magazine.
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