Significant figures

Significant figures, also referred to as significant digits or sig figs, are specific digits within a number written in positional notation that carry both reliability and necessity in conveying a particular quantity. When presenting the outcome of a measurement (such as length, pressure, volume, or mass), if the number of digits exceeds what the measurement instrument can resolve, only the number of digits within the resolution's capability are dependable and therefore considered significant.

Not to be confused with Significant Figures (book).

For instance, if a length measurement yields 114.8 mm, using a ruler with the smallest interval between marks at 1 mm, the first three digits (1, 1, and 4, representing 114 mm) are certain and constitute significant figures. Further, digits that are uncertain yet meaningful are also included in the significant figures. In this example, the last digit (8, contributing 0.8 mm) is likewise considered significant despite its uncertainty.^[1] Therefore, this measurement contains four significant figures.

Another example involves a volume measurement of 2.98 L with an uncertainty of ± 0.05 L. The actual volume falls between 2.93 L and 3.03 L. Even if certain digits are not completely known, they are still significant if they are meaningful, as they indicate the actual volume within an acceptable range of uncertainty. In this case, the actual volume might be 2.94 L or possibly 3.02 L, so all three digits are considered significant.^[1] Thus, there are three significant figures in this example.

The following types of digits are not considered significant:^[2]

A zero after a decimal (e.g., 1.0) is significant, and care should be used when appending such a decimal of zero. Thus, in the case of 1.0, there are two significant figures, whereas 1 (without a decimal) has one significant figure.

Among a number's significant digits, the most significant digit is the one with the greatest exponent value (the leftmost significant digit/figure), while the least significant digit is the one with the lowest exponent value (the rightmost significant digit/figure). For example, in the number "123" the "1" is the most significant digit, representing hundreds (10²), while the "3" is the least significant digit, representing ones (10⁰).

To avoid conveying a misleading level of precision, numbers are often rounded. For instance, it would create false precision to present a measurement as 12.34525 kg when the measuring instrument only provides accuracy to the nearest gram (0.001 kg). In this case, the significant figures are the first five digits (1, 2, 3, 4, and 5) from the leftmost digit, and the number should be rounded to these significant figures, resulting in 12.345 kg as the accurate value. The rounding error (in this example, 0.00025 kg = 0.25 g) approximates the numerical resolution or precision. Numbers can also be rounded for simplicity, not necessarily to indicate measurement precision, such as for the sake of expediency in news broadcasts.

Significance arithmetic encompasses a set of approximate rules for preserving significance through calculations. More advanced scientific rules are known as the propagation of uncertainty.

Radix 10 (base-10, decimal numbers) is assumed in the following. (See unit in the last place for extending these concepts to other bases.)

Non-zero digits within the given measurement or reporting resolution

Zeros between two significant non-zero digits

Zeros to the left of the first non-zero digit

Zeros to the right of the last non-zero digit () in a number with the decimal point

trailing zeros

Trailing zeros in an integer

scientific notation

An exact number has an infinite number of significant figures.

A mathematical or physical constant has significant figures to its known digits.

real number

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Writing uncertainty and implied uncertainty[edit]

Significant figures in writing uncertainty[edit]

It is recommended for a measurement result to include the measurement uncertainty such as $x_{best}\pm \sigma _{x}$ , where x_best and σ_x are the best estimate and uncertainty in the measurement respectively.^[10] x_best can be the average of measured values and σ_x can be the standard deviation or a multiple of the measurement deviation. The rules to write $x_{best}\pm \sigma _{x}$ are:^[11]

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log₁₀(3.000 × 10⁴) = log₁₀(10⁴) + log₁₀(3.000) = 4.000000... (exact number so infinite significant digits) + 0.4771212547... = 4.4771212547 ≈ 4.4771.

Estimating an extra digit[edit]

When using a ruler, initially use the smallest mark as the first estimated digit. For example, if a ruler's smallest mark is 0.1 cm, and 4.5 cm is read, then it is 4.5 (±0.1 cm) or 4.4 cm to 4.6 cm as to the smallest mark interval. However, in practice a measurement can usually be estimated by eye to closer than the interval between the ruler's smallest mark, e.g. in the above case it might be estimated as between 4.51 cm and 4.53 cm.^[15]

It is also possible that the overall length of a ruler may not be accurate to the degree of the smallest mark, and the marks may be imperfectly spaced within each unit. However assuming a normal good quality ruler, it should be possible to estimate tenths between the nearest two marks to achieve an extra decimal place of accuracy.^[16] Failing to do this adds the error in reading the ruler to any error in the calibration of the ruler.

Delury, D. B. (1958). "Computations with approximate numbers". The Mathematics Teacher. 51 (7): 521–30. :10.5951/MT.51.7.0521. JSTOR 27955748.

doi

Bond, E. A. (1931). "Significant Digits in Computation with Approximate Numbers". The Mathematics Teacher. 24 (4): 208–12. :10.5951/MT.24.4.0208. JSTOR 27951340.

doi

E29-06b, Standard Practice for Using Significant Digits in Test Data to Determine Conformance with Specifications

ASTM

Significant Figures Video by Khan academy

The Decimal Arithmetic FAQ — Is the decimal arithmetic ‘significance’ arithmetic?

and some explanations of the shortcomings of significance arithmetic and significant figures.

Advanced methods for handling uncertainty

– Displays a number with the desired number of significant digits.

Significant Figures Calculator

– Proper methods for expressing uncertainty, including a detailed discussion of the problems with any notion of significant digits.

Measurements and Uncertainties versus Significant Digits or Significant Figures

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