Multifunction DAQ

Hi KyleL12,

The absolute accuracy is the worse-case error for measurement of a DAQ device, in other words how close the measurement is to the actual true value of the signal. This is explained pretty well at the very bottom of the second link you attached. That is true that as long as the device is within calibration these absolute accuracy numbers are valid. Does this answer your question? Or did you have any other specific questions you were looking to have answered?

-will.i.am10

I am trying to figure out how Absolute Accuracy (AA) works into a GUM uncertainty budget. Since National Instruments does a GUM analysis for a certain product and not for other devices, I am wanting to make sure I define the AA properly for the GUM analysis. They are a few ways I can do this depending on what AA exactly is.

If AA is really the difference between a true value and a measured value.  I would think this could be done say AA = 0.003 V, then V = 5.000 and Vcrr = 5.003.  Or maybe I guess AA is the uncertainty of in the difference of Vtrue - Vdaq.  Based on the language, it is an extended uncertainty and I would have to determine the standard uncertainty from it for the GUM.  It would be nice to make sure I have a reasonable assumption on the distribution and "confidence" of this error.  Even if the information isn't available, it might be known of errors that occur have a central tendency in the range of AA, etc.  The handbook I am using discourages simply defaulting to a rectangular (or uniform) distribution as they are certain criteria to be met for this distribution.

I have actually tried to search the internet for published works that used NI hardware with AA spec and reported uncertainty budgets.  The works I came across have treated the AA treated them as an extended uncertainty, yet quite a few of the works don't provide the details behind their budgets.  Interestingly, they would combine the gain and the offset components of the AA in a Root Sum of the Squares manner, which I think would be interesting to clarify too.  Based on NI's notes and what I know of accuracy specifications in the form of %*Reading + Least Significant Digit for say a Digital Multi-meter, then the components of the AA should be combined by the equations provided NI. It then can be used as an uncertainty.  

Hi KyleL12,

I can’t say for certain how these absolute accuracy values apply to the GUM analysis. If you have any questions about the AA of the devices, I will be happy to help. It sounds like you have a pretty good idea on the meaning of AA and understand what the values mean, but are just looking for how to apply them to your analysis. If I am misunderstanding this and you do have questions about the AA feel free to let me know!

-will.i.am10

You are correct.  I think I was starting to over think it. After taking a closer look at the links as you responded to my question, the absolute accuracy is an uncertainty as in the example at the end of the first link.  I should just make my assumptions and use in my calculations. Unfortunately, this is not the toughest part of my analysis.