4-20mA Sensor Interface Guide: Difference between revisions

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[[Category:Primer]]
{{#seo:|description=Learn the basics about 4-20mA sensors with this guide. This includes: how they work, advantages and disadvantages, and when to consider using these sensors.}}
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[[Category:IntroGuide]]
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==Introduction==
==Introduction==
 
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A 4-20mA sensor interface is a small device that adapts a 2-wire 4-20mA sensor's output so it can be read by your computer.  
Normally, 4-20mA sensors are intended for industrial use, and are difficult to use with a computer. However, with a {{CT|420Adapter|4-20mA adapter Phidget}}, interfacing with these sensors is extremely simple.
 
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Normally, 4-20mA sensors are intended for industrial use and are difficult to use with a computer.  
However, with a 4-20mA sensor interface and the associated Phidgets hardware, these sensors can be used as easily as an ordinary 0-5 volt sensor.
 
You can find options for 4-20mA adapters (in addition to other types of adapters) on our [{{SERVER}}/?tier=1&catid=49&pcid=42 Adapters] category page.
 
==How it works==
==How it works==
===Overview===
[[Image:420Interface.png|500px|link=|thumb|Traditional setup for reading a 4-20mA sensor.]]
4-20mA is an electrical standard for connecting sensors to a ''data acquisition device'' (DAQ). A 4-20mA sensor has two wires. One wire is used to power the sensor, and the other is a ground. The sensor sends data to the DAQ in the form of the amount of current it consumes. For example, a 4-20mA velocity sensor might consume 4mA when it is sensing zero movement, and would output 20mA when the sensor is moving at the maximum velocity it can sense. 4-20mA sensors are usually expensive and intended for industrial purposes. There are often less expensive 0-5V analog versions available.


Before understanding what the 4-20mA sensor interface does, it's useful to know how a 4-20mA sensor is different from a 0-5 volt sensor.
===Advantages of a 4-20mA Sensor===
 
*You can use longer wires with a 4-20mA sensor, since the data values are sent in the form of current rather than voltage levels that drop off with distance. However, you should ensure that the minimum voltage required to power the sensor is present at the end of the wire. To check, use a multimeter to measure the voltage across the two wires connecting to the sensor, when the sensor is measuring it's maximum value (and therefore drawing close to 20mA of current). If the voltage is higher than the minimum required voltage of the sensor (found in the sensor's data sheet), then it should be fine. Please note that twisted pair wire is the best for these long wire applications.
====4-20mA Sensors====
*4-20mA sensors are less susceptible to electromagnetic interference (EMI). This is because the data is sent in the form of current, which is less susceptible to EMI than voltage.  
 
*It is easier to tell when your system has failed with a 4-20mA sensor. When a 4-20mA sensor senses its minimum value, it consumes 4mA of current. If it ever consumes zero current, it means there is a broken wire or some other failure in the system. When a 0-5V sensor fails in this way, the data line would read zero volts, which could mean it's just sensing zero.  
[[Image:420Interface.png|400px|link=|thumb|Traditional setup for reading a 4-20mA sensor.<br/>[[Media:420Interface.png|Full-sized Image]]]]
===Disadvantages of a 4-20mA Sensor===
 
* Usually more expensive than 0-5V sensors.
4-20mA is an electrical standard for connecting sensors to a '''data acquisition device''' (DAQ). A 4-20mA sensor has two wires. One wire is used to power the sensor, and the other is a ground. The sensor sends data to the DAQ in the form of the amount of current it consumes. For example, a 4-20mA velocity sensor might consume 4mA when it is sensing zero movement, and would output 20mA when the sensor is moving at the maximum velocity it can sense.  4-20mA sensors are usually expensive and intended for industrial purposes. There are often less expensive 0-5V analog versions available.
 
'''Advantages of a 4-20mA Sensor:'''
* You can use longer wires with a 4-20mA sensor, since the data values are sent in the form of current rather than voltage levels that drop off with distance. However, you should ensure that the minimum voltage required to power the sensor is present at the end of the wire. To check, use a multimeter to measure the voltage across the two wires connecting to the sensor, when the sensor is measuring it's maximum value (and therefore drawing close to 20mA of current). If the voltage is higher than the minimum required voltage of the sensor (found in the sensor's data sheet), then it should be fine. Please note that twisted pair wire is the best for these long wire applications.
 
* 4-20mA sensors are less susceptible to electromagnetic interference (EMI) . This is because the data is sent in the form of current, which is less susceptible to EMI than voltage.  
 
* It is easier to tell when your system has failed with a 4-20mA sensor. When a 4-20mA sensor senses its minimum value, it consumes 4mA of current. If it ever consumes zero current, it means there is a broken wire or some other failure in the system. When a 0-5V sensor fails in this way, the data line would read zero volts, which could mean it's just sensing zero.  
 
'''Disadvantages of a 4-20mA Sensor:'''
* Usually more expensive than 0-5 volt sensors
* 4-20mA sensors are not very efficient, because they only need 4mA to function, and any additional current draw exists solely to communicate the value it is sensing
* 4-20mA sensors are not very efficient, because they only need 4mA to function, and any additional current draw exists solely to communicate the value it is sensing
 
===When to use a 4-20mA Sensor===
'''When to use a 4-20mA Sensor:'''
* If you already own a 4-20mA sensor and don't want to buy an analog version.
* If you already own a 4-20mA sensor and don't want to buy an analog version
* You need to use a very long wire between the sensor and the power source.
* You need to use a very long wire between the sensor and the power source
* The environment has a lot of electromagnetic interference.
* The environment has a lot of electromagnetic interference
* The sensor is only available in the 4-20mA format.
* The sensor is only available in the 4-20mA format
 
====4-20mA Sensor Interface====
 
Now that we've covered how a 4-20mA sensor is different from a 0-5 volt sensor, the basic operation of a 4-20mA sensor interface should be clear. It simply powers the sensor and monitors the current consumption on the power line. It then converts the 4-20mA value either to a 0-5 volt signal or a VINT communication packet at its output, depending on what kind of Phidget you're using.
 
===Basic Use===
 
Using a 4-20mA sensor interface with Phidgets is very simple. Simple connect the sensor's wires to the interface as described in your Phidget's [[:Category:UserGuide|User Guide]]. Check the sensor's data sheet to determine how your program should interpret the data it is receiving.

Latest revision as of 20:10, 26 June 2023

Introduction

DAQ1400 0.jpg

Normally, 4-20mA sensors are intended for industrial use, and are difficult to use with a computer. However, with a 4-20mA adapter Phidget, interfacing with these sensors is extremely simple.

How it works

Overview

Traditional setup for reading a 4-20mA sensor.

4-20mA is an electrical standard for connecting sensors to a data acquisition device (DAQ). A 4-20mA sensor has two wires. One wire is used to power the sensor, and the other is a ground. The sensor sends data to the DAQ in the form of the amount of current it consumes. For example, a 4-20mA velocity sensor might consume 4mA when it is sensing zero movement, and would output 20mA when the sensor is moving at the maximum velocity it can sense. 4-20mA sensors are usually expensive and intended for industrial purposes. There are often less expensive 0-5V analog versions available.

Advantages of a 4-20mA Sensor

  • You can use longer wires with a 4-20mA sensor, since the data values are sent in the form of current rather than voltage levels that drop off with distance. However, you should ensure that the minimum voltage required to power the sensor is present at the end of the wire. To check, use a multimeter to measure the voltage across the two wires connecting to the sensor, when the sensor is measuring it's maximum value (and therefore drawing close to 20mA of current). If the voltage is higher than the minimum required voltage of the sensor (found in the sensor's data sheet), then it should be fine. Please note that twisted pair wire is the best for these long wire applications.
  • 4-20mA sensors are less susceptible to electromagnetic interference (EMI). This is because the data is sent in the form of current, which is less susceptible to EMI than voltage.
  • It is easier to tell when your system has failed with a 4-20mA sensor. When a 4-20mA sensor senses its minimum value, it consumes 4mA of current. If it ever consumes zero current, it means there is a broken wire or some other failure in the system. When a 0-5V sensor fails in this way, the data line would read zero volts, which could mean it's just sensing zero.

Disadvantages of a 4-20mA Sensor

  • Usually more expensive than 0-5V sensors.
  • 4-20mA sensors are not very efficient, because they only need 4mA to function, and any additional current draw exists solely to communicate the value it is sensing

When to use a 4-20mA Sensor

  • If you already own a 4-20mA sensor and don't want to buy an analog version.
  • You need to use a very long wire between the sensor and the power source.
  • The environment has a lot of electromagnetic interference.
  • The sensor is only available in the 4-20mA format.