B Implicit error margins based on significant figures

AI Thread Summary
The discussion centers on the confusion surrounding significant figures and implicit error margins in physics problems, particularly when measurements are presented without explicit error margins. Participants note that many physics textbooks emphasize significant figures but often omit error margins, leading to questions about the validity of this practice. The convention that significant figures imply a margin of error is acknowledged, with examples illustrating how precision varies based on the context of the measurement. There is a call for better educational resources that address implicit error margins more thoroughly, as current texts often fall short. Overall, the conversation highlights the need for clarity in teaching measurement accuracy and its implications in both theoretical and practical applications.
johann1301h
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A discussion on the relationship between error margins and significant figures.
WARNING: Topic is very pedantic.

I have used a set of different physics books over the years, and they have all had a focus on the topic of significant figures, error margins and measurement. I have never quite understood these concepts fully and the relationships between them.

One aspect I want to address in this discussion is measurements written without error margins. To be clear, a measurement with error margins could be 201 ± 7, and without would just be 201. The main reason motivating this, is that 99% of the physics problems I have encountered provide their numbers without any error margins. The books providing these problems all seem to be in the opinion of writing the answer with a certain amount of significant figures.

If the books don’t provide any error margins, why do they want us to answer with a specific number of significant figures?

My current answer to this, is that the numbers are assumed to be the result of some (hypothetical) experiment and that the margins must be implicit (sort of like how 4 implicitly means +4).

I did find a statement on Wikipedia regarding implicit error margins, which reads as follows;

A common convention in science and engineering is to express accuracy and/or precision implicitly by means of significant figures. Where not explicitly stated, the margin of error is understood to be one-half the value of the last significant place. For instance, a recording of 843.6 m, or 843.0 m, or 800.0 m would imply a margin of 0.05 m (the last significant place is the tenths place), while a recording of 843 m would imply a margin of error of 0.5 m (the last significant digits are the units).

Im wondering how much this convention is used, where I can read more about it, and if there are anyone here who can confirm that this is a valid and used principle. For instance, where does it come in use?

I started reading An introduction to error analysis, but so far, the book seems to skips the detail regarding implicit error margins.

Anyway, is anyone here pedantic enough to address how physics problems often require/motivates a constrained answer with significant figures, while at the same time, the problems only provide numbers without any error margins at all.

I can understand that it would be very cumbersome if all the problems would always include error margins since it would require more effort of calculating the answer, and in terms of additional print space for each problem. But still, when doing real life physics, in a lab, can these non-margin problems really compare at all?

It seems to me that these problems we find in physics books only address the topic of error analysis half-way.

In my - current - opinion, if they don’t address the topic in a realistic way, why address the topic at all. That is, why should we care to write the answers in a constrained way with “a correct” amount of significant numbers.

Merry Christmas, and hope 2021 will be a better year for you all!
 
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It seems to depend if the book is a textbook (with hypothetical situations) vs real world situations (practice) where the precision of the variables is very much important. An explicit section on error margins should bring up the points that you do.

So for instance, a textbook might reference sin(3 degrees) which is given with 1 digit of precision*, but the computation is not expecting you to use 5e-2. The text is probably expecting 0.052336 to be used, and I only stopped there because it would take two more digits to be meaningfully more precise.

In practice, the precision to which the 3 degrees is known makes all the difference in the world as to the precision with which the resulting computation is to be considered meaningful. Yes, the convention you quote is the one typically used. Precision is often known to x many digits where x can vary by halves, so a measurement of 0.1276 meters is considered to be 3.5 digits of precision.

Also, the precision of one measurement might result in a computation that is known to more or fewer significant digits. For instance, cos(8.2 deg) ±0.05deg) is has 2 digits of input precision but 3.5 digits of output precision. Thus it is sometimes a mistake to carry all computations to some minimum precision (weakest link so to speak).

*Anything in degrees is actually automatically 3 digits of precision left of the decimal. 3 degrees is no more or less precise than 73 or 245891 degrees.
 
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johann1301h said:
. . . is anyone here pedantic enough . . .
How do we measure that?
 
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Halc said:
It seems to depend if the book is a textbook (with hypothetical situations) vs real world situations (practice) where the precision of the variables is very much important. An explicit section on error margins should bring up the points that you do.

The book I am currently reading is Serway Physics for scientists and engineers. It does not adress the topic of implicit error margins, but does adress how to calculate error from a non error margin number set.
 
Yes, the convention you quote is the one typically used. Precision is often known to x many digits where x can vary by halves, so a measurement of 0.1276 meters is considered to be 3.5 digits of precision.

Are there any good textbooks covering this?
 
sysprog said:
How do we measure that?

Whatever the SI unit of pedantry is, I'm sure a different unit is in common use in the USA.
 
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Vanadium 50 said:
Whatever the SI unit of pedantry is, I'm sure a different unit is in common use in the USA.
We use an inverse scale calibrated in [insert political figure's name here]s.
 
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johann1301h said:
Are there any good textbooks covering this?

Taylor, An Introduction To Error Analysis. Is quite good. You can judge a book by its cover:
1608750754105.png


However, significant figures are more a rule of thumb than a rigorous calculational tool, so nobody would write an entire book about them. Think of them as a way to keep you from writing anything completely idiotic. "The dinosaurs died 65,000,002 years ago."
 
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Vanadium 50 said:
Taylor, An Introduction To Error Analysis. Is quite good.

Thanks for the response, but as I wrote in the OP, this book skips the topic of implicit error margins. (based on my initial reading)
 
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And, for the reasons I mentioned above, I don't think you will find a book that does this.
 
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Vanadium 50 said:
... so nobody would write an entire book about them.

giphy.gif
 
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johann1301h said:
[challenge accepted]
If you're contemplating writing a book on that, (shameless unsolicited plugging of PF here) maybe you could try writing an Insights article on it here first?
 
  • #13
Vanadium 50 said:
However, significant figures are more a rule of thumb than a rigorous calculational tool,
But a very useful rule of thumb when using a slide rule.
 
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Nugatory said:
using a slide rule

What is this "slide rule" of which you speak?

sliderule-magnetism.jpg
 
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  • #15
johann1301h said:
Im wondering how much this convention is used, where I can read more about it, and if there are anyone here who can confirm that this is a valid and used principle. For instance, where does it come in use?

What is stated on Wikipedia is a conventional rule of thumb. You can find it taught in many high school science textbooks.
https://www.bbc.co.uk/bitesize/guides/z3dt3k7/revision/4
https://www.bbc.co.uk/bitesize/guides/zv3rd2p/revision/5
https://www.dartmouth.edu/~genchem/sigfigs.html
 
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Nugatory said:
But a very useful rule of thumb when using a slide rule.
When I was a kid (early '70s) the Math teacher told us that: for a slide rule, two more digits of accuracy at the same visual scale would require a hundred times the size, whereas a calculator with two more digits of accuracy could still fit in a coat pocket.
 
  • #17
sysprog said:
When I was a kid (early '70s) the Math teacher told us that: for a slide rule, two more digits of accuracy at the same visual scale would require a hundred times the size, whereas a calculator with two more digits of accuracy could still fit in a coat pocket.
Two significant digits is plenty for many interesting and important real world problems.
I've seen an engineering professor from the early calculator days quoted as saying that if you're looking at the second significant digit of the tensile strength... you've already made a mistake.
 
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  • #18
Nugatory said:
Two significant digits is plenty for many interesting and important real world problems.
I've seen an engineering professor from the early calculator days quoted as saying that if you're looking at the second significant digit of the tensile strength... you've already made a mistake.
From https://www.discovermagazine.com/technology/the-first-nerd-tool:
1608843305784.png


The five-inch Keuffel & Esser Deci-Lon, the quintessential 1960s pocket slide rule, cost $12.50. Recently one sold on eBay for $180. Chemist Linus Pauling used to astound freshmen at Caltech by multiplying numbers to six decimal places on his pocket slide rule. "He calculated the last two digits in his head," says Caltech math professor emeritus Tom Apostol.

And a slide rule was present at the creation of the nuclear age—Enrico Fermi used his to calculate exactly how far a cadmium control rod should be pulled from a graphite and uranium pile as he demonstrated the first controlled nuclear chain reaction at the University of Chicago in 1942. Moments after making the final calculation, Fermi put away his slide rule, smiled broadly, and announced, "The reaction is self-sustaining."
Even with my Flying Fish log log vector slide rule, I'm still not accomplishing that much ##-## what's up with that?

1608844631165.png
 
  • #19
I believe the GUM actually discusses this, at least briefly

https://www.bipm.org/en/publications/guides/gum.html

Note that since the GUM is the official guide from BIPM is it -quite literally- always the primary source as long as you are dealing with measurement results expressed using SI units
Also, the GUM and its various supplements is surprisingly readable.
 
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