Understanding “True Analog” Resolution

Many distance measurement sensors – regardless of the front-end sensing technology employed – deliver an analog output such as 0-10V or 4-20mA.   A key parameter to understand for any distance measurement sensor is the output resolution.   In a position measurement system, resolution is defined as:     

The smallest increment of position change which can be detected and indicated by the output.      

To understand the ultimate resolution of a given sensor, it is necessary to understand how the device functions to generate the analog output.  In a true analog sensor, the output is developed by purely analog circuitry, without the use of a digital-to-analog converter (a.k.a. DAC: we’ll cover digitally-derived analog outputs in a future post).  In a true analog sensor, the output change is continuous and infinitely variable.  In theory the resolution is infinite, but in practice it is not…read on to find out why.     

Factors Affecting True Analog Resolution

 In sensors delivering a true analog output, practical resolution is determined primarily by:     

  • The noise on the output and/or signal lines
  • The input resolution of the device to which the sensor is connected

 Noise – This is the main limiting factor in most measurement systems.  Even if the resolution of the sensor is theoretically infinite, it’s only possible to resolve signal changes that are larger than the amount of noise on the output signal lines.  Output changes smaller than the noise level are “lost” in the noise.      

Effect of noise on the analog output of a distance sensor

Analog Noise on an Ideal Analog Output Signal

        

        

      

 

 

 

 
Determining Sensor Resolution – A Practical Example
 Sensor Type:  Magneto-Inductive Linear Position Sensor     

Measurement Length:  60 mm (2.36″)     

Output Range:  0-10 Vdc     

System Noise Level:   10 mV     

In this example, the infinitely variable output signal of the sensor is limited by the fact that there is 10 mV of noise present on the signal lines.   Since 10 mV is 1/1000th of the entire 0-10V range, the smallest position change that can be detected is 1/1000th of the working stroke range of 2.36”:      2.36 / 1000 = 0.00236” 

So a good, practical estimate of the resolution is 0.0024”.  Assuming a lower noise level would result in a better estimated resolution, e.g., 5 mV = 0.0012”    

Understanding Controller Input Resolution     

Analog inputs on industrial controls must “digitize” an analog signal in order to utilize the information.   This is accomplished using an Analog-to-Digital Converter (ADC).  An ADC accepts the analog signal and assigns a discrete, digital value to a defined signal value.     

True Analog Sensor into an ADC

Analog-to-Digital Converter

For example, a 12-bit ADC can represent a 0-10V signal as any one of 4,096 “numbers” (212 = 4,096).   Using the above example:  2.36” / 4,096 = 0.00058”     

Important – Note that, in the above example, the limitation as a result of noise is still the determining factor.  Even though the input resolution can be as good as 0.00058”, the 10 mV noise level would still limit practical resolution to 0.00236”.


Share/Bookmark

This entry was posted in Analog Position Sensors, Linear Position and Distance Measurement. Bookmark the permalink.

3 Responses to Understanding “True Analog” Resolution

  1. Pingback: Digitally Derived Analog Signals « Sensor Technology

  2. Pingback: Resolution, Accuracy and Repeatability – «

  3. Pingback: Do Photoelectric Sensors Really Measure Up? « SensorTech

What do you think?

Fill in your details below or click an icon to log in:

WordPress.com Logo

You are commenting using your WordPress.com account. Log Out / Change )

Twitter picture

You are commenting using your Twitter account. Log Out / Change )

Facebook photo

You are commenting using your Facebook account. Log Out / Change )

Google+ photo

You are commenting using your Google+ account. Log Out / Change )

Connecting to %s