Chem1 General Chemistry Virtual Textbook
The measure of matter
Significant figures and rounding off
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The numerical values we deal with in science (and in many other aspects of life) represent measurements whose values are never known exactly. Our pocket-calculators or computers don't know this; they treat the numbers we punch into them as "pure" mathematical entities, with the result that the operations of arithmetic frequently yield answers that are physically ridiculous even though mathematically correct.
The purpose of this unit is to help you understand why this happens, and show you what to do about it.
Consider the two statements shown here. Which of these would you be justified in dismissing immediately? Certainly not the second one, because it probably comes from a database which contains one record for each voter, so the number is found simply by counting the number of records.
The first statement cannot possibly be correct. Even if a citys population could be defined in a precise way (Permanent residents? Warm bodies?), how can we account for the minute-by minute changes that occur as people are born and die, or move in and move away?
What is the difference between the two population numbers stated above? The first one expresses a quantity that cannot be known exactly that is, it carries with it a degree of uncertainty. It is quite possible that the last census yielded precisely 157,872 records, and that this might be the population of the city for legal purposes, but it is surely not the true population. To better reflect this fact, one might list the population (in an atlas, for example) as 157,900 or even 158,000. These two quantities have been rounded off to four and three significant figures, respectively, and the have the following meanings:
Which of these two values we would report as the population will depend on the degree of confidence we have in the original census figure; if the census was completed last week, we might round to four significant digits, but if it was a year or so ago, rounding to three places might be a more prudent choice. In a case such as this, there is no really objective way of choosing between the two alternatives.
This illustrates an important point: the concept of significant digits has less to do with mathematics than with our confidence in a measurement. This confidence can often be expressed numerically (for example, the height of a liquid in a measuring tube can be read to ±0.05 cm), but when it cannot, as in our population example, we must depend on our personal expereience and judgement.
So, what is a significant digit? According to the usual definition, it is all the numerals in a measured quantity (counting from the left) whose values are considered as known exactly, plus one more whose value could be one more or one less:
In 157900 (four significant digits), the leftmost three digits are known exactly, but the fourth digit, 9 could well be 8 if the true value is within the implied range of 157850 to 157950.
In 158000 (three significant digits), the leftmost two digits are known exactly, while the third digit could be either 7 or 8 if the true value is within the implied range of 157500 to 158500.
Although rounding off always leads to the loss of numeric information, what we are getting rid of can be considered to be numeric noise that does not contribute to the quality of the measurement.
If you know that a balance is accurate to within 0.1 mg, say, then the uncertainty in any measurement of mass carried out on this balance will be ±0.1 mg. Suppose, however, that you are simply told that an object has a length of 0.42 cm, with no indication of its precision. In this case, all you have to go on is the number of digits contained in the data. Thus the quantity 0.42 cm is specified to 0.01 unit in 0 42, or one part in 42 . The implied relative uncertainty in this figure is 1/42, or about 2%. The precision of any numeric answer calculated from this value is therefore limited to about the same amount.
It is important to understand that the number of significant digits in a value provides only a rough indication of its precision, and that information is lost when rounding off occurs.
Suppose, for example, that we measure the weight of an object as 3.28 g on a balance believed to be accurate to within ±0.05 gram. The resulting value of 3.28±.05 gram tells us that the true weight of the object could be anywhere between 3.23 g and 3.33 g. The absolute uncertainty here is 0.1 g (±0.05 g), and the relative uncertainty is 1 part in 32.8, or about 3 percent.
How many significant digits should there be in the reported measurement? Since only the leftmost 3 in 3.28 is certain, you would probably elect to round the value to 3.3 g. So far, so good. But what is someone else supposed to make of this figure when they see it in your report? The value 3.3 g suggests an implied uncertainty of 3.3±0.05 g, meaning that the true value is likely between 3.25 g and 3.35 g. This range is 0.02 g below that associated with the orginal measurement, and so rounding off has introduced a bias of this amount into the result. Since this is less than half of the ±0.05 g uncertainty in the weighing, it is not a very serious matter in itself. However, if several values that were rounded in this way are combined in a calculation, the rounding-off errors could become significant.
The standard rules for rounding off are well known. Before we set them out, let us agree on what to call the various components of a numeric value.
The rules for rounding off are shown here.
Students are sometimes told to increment the least significant digit by 1 if it is odd, and to leave it unchanged if it is even. One wonders if this reflects some idea that even numbers are somehow better than odd ones! (The ancient superstition is just the opposite, that only the odd numbers are "lucky".)
In fact, you could do it equally the other way around, incrementing only the even numbers. If you are only rounding a single number, it doesnt really matter what you do. However, when you are rounding a series of numbers that will be used in a calculation, if you treated each first-nonsignificant 5 in the same way, you would be over- or underestating the value of the rounded number, thus accumulating round-off error. Since there are equal numbers of even and odd digits, incrementing only the one kind will keep this kind of error from building up.
You could do just as well, of course, by flipping a coin!
number to round / no. of sig. digits |
result |
comment |
34.216 / 3 | 34.2 | First non-significant digit (1) is less than 5, so number is simply truncated. |
2.252 / 2 | 2.2 or 2.3 | First non-significant digit is 5, so least sig. digit can either remain unchanged or be incremented. |
39.99 / 3 | 40.0 | Crossing "decimal boundary", so all numbers change. |
85,381 / 3 | 85,400 | The two zeros are just placeholders |
0.04597 / 3 | 0.0460 | The two leading zeros are not significant digits. |
Suppose that an object is found to have a weight of 3.98 ± 0.05 g. This would place its true weight somewhere in the range of 3.93 g to 4.03 g. In judging how to round this number, you count the number of digits in 3.98 that are known exactly, and you find none! Since the 4 is the leftmost digit whose value is uncertain, this would imply that the result should be rounded to one significant figure and reported simply as 4 g. An alternative would be to bend the rule and round off to two significant digits, yielding 4.0 g. How can you decide what to do?
In a case such as this, you should look at the implied uncertainties in the two values, and compare them with the uncertainty associated with the original measurement.
rounded value |
implied max |
implied min |
absolute uncertainty |
relative uncertainty |
3.98 g | 3.985 g | 3.975 g | ±.005 g or 0.01 g | 1 in 400, or 0.25% |
4 g | 4.5 g | 3.5 g | ±.5 g or 1 g | 1 in 4, 25% |
4.0 g | 4.05 g | 3.95 g | ±.05 g or 0.1 g | 1 in 40, 2.5% |
Clearly, rounding off to two digits is the only reasonable course in this example.
The same kind of thing could happen if the original measurement was 9.98 ± 0.05 g. Again, the true value is believed to be in the range of 10.03 g to 9.93 g. The fact that no digit is certain here is an artifact of decimal notation. The absolute uncertainty in the observed value is 0.1 g, so the value itself is known to about 1 part in 100, or 1%. Rounding this value to three digits yields 10.0 g with an implied uncertainty of ±.05 g, or 1 part in 100, consistent with the uncertainty in the observed value.
Observed values should be rounded off to the number of digits that most accurately conveys the uncertainty in the measurement.
In science, we frequently need to carry out calculations on measured values. For example, you might use your pocket calculator to work out the area of a rectangle:
rounded value |
precision |
1.58 | 1 part in 158, or 0.6% |
1.6 | 1 part in 16, or 6 % |
Comment: Your calculator is of course correct as far as the pure numbers go, but you would be wrong to write down 1.57676 cm2 as the answer. Two possible options for rounding off the calculator answer are shown below:
It is clear that neither option is entirely satisfactory; rounding to 3 significant digits leaves the answer too precisely specified, whereas following the rule and rounding to 2 digits has the effect of throwing away some precision. In this case, it could be argued that rounding to three digits is justified because the implied relative uncertainty in the answer, 0.6%, is more consistent with those of the two factors.
The above example is intended to point out that the rounding-off rules, although convenient to apply, do not always yield the most desirable result.
Other examples of rounding calculated values based on measurements are given below.
calculator result |
rounded |
remarks |
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1.6 |
Rounding to two significant figures yields an implied uncertainty of 1/16 or 6%, three times greater than that in the least-preciseely known factor. This is a good illustration of how rounding can lead to the loss of information. |
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1.9E6 |
The "3.1" factor is specified to 1 part in 31, or 3%. In the answer 1.9, the value is expressed to 1 part in 19, or 5%. These precisions are comparable, so the rounding-off rule has given us a reasonable result. |
A certain book has a thickness of 117 mm; find the height of a stack of 24 identical books:
|
2810 mm |
The 24 and the 1 are exact, so the only uncertain value is the thickness of each book, given to 3 significant digits. The trailing zero in the answer is only a placeholder. |
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10.4 |
In addition or subtraction, look for the term having the smallest number of decimal places, and round off the answer to the same number of places. |
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23 cm |
[see below] |
The last of the examples shown above represents the very common operation of converting one unit into another. There is a certain amount of ambiguity here; if we take "9 in" to mean a distance in the range 8.5 to 9.5 in, then the uncertainty is ±0.5 in, which is 1 part in 18, or about ± 6%.
The relative uncertainty in the answer must be the same, since all the values are multiplied by the same factor, 2.54 cm/in. In this case we are justified in writing the answer to two significant digits, yielding an uncertainty of about ±4 cm; if we had used the answer "20 cm" (one significant digit), its implied uncertainty would be ±5 cm, or ±25%.
The excellent Significant figures tutorial by David Dice allows you to test your understanding as you go along.
Make sure you thoroughly understand the following essential ideas which have been presented above. It is especially imortant that you know the precise meanings of all the highlighted terms in the context of this topic.
You can download a pdf document suitable for viewing or printing that contains
all five sections of the "Matter-and-measure" unit.
Page last modified: 12.08.2010
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