Significant Figures: Introduction and Example (2021)

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Rounding of numbers is done so that one can concentrate on the most significant digits. For example, consider a flat price at 285500. A rich man might think in hundreds of thousands of dollars. To a rich man, it is easier to think in terms of 1 significant figure, the “3” in 300,000. A wage might be worried about the hundreds of dollars. To him, there may be four significant figures, the ‘2’, ‘8’, ‘5’, and ‘5’ in 285500.

Significant Figures Example

Consider an example: A weight recorded as 8426kg is correct to 3 decimal places. Reporting this weight in grams, the 8425g is nearest to the whole number. Recording the weight as 8.426kg correct to 4 significant figures and converting the weight to 8426g, the number of significant figures is still 4. Thus, sometimes it is more useful to express a result in terms of numbers of significant figures rather than the number of decimal places.

There are some rules for writing significant figures:

Rule 1: Include one extra figure for consideration. Simply drop the extra figure if it is less than 5. If it is 5 or more, add 1 to the previous figure before dropping the extra figure.

Rule 2: All non-zero digits are significant wherever they are recorded. For example, 7.22 is correct to 3 significant figures.

Rule 3: Zeros that lie between non-zero digits are significant. For example, 2003 is correct for 4 significant figures.
Rule 4: Zeros that are not preceded by a non-zero digit (leading zeros) are not significant. For example, 0.000325 is correct to 3 significant digits.

Rule 5: Zeros that appear after the decimal points (trailing zeros) but are not followed by a non-zero digit are significant. For example, there are 5 significant digits in 22.300.

Rule 6: The final zeros in a whole number may or may not be significant. It depends on how the estimation is made.

Significant Figures

A point to remember is that the number of digits is used to denote an exact value to a specified degree of accuracy. For example, 6084.324 is a value accurate to 7 significant figures. If written as 6080 it is accurate to 3 significant digits. The final 0 is not significant because it is used to show the order of magnitude of the number.

Significant Figures

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Percentages, Fractions, and Decimals Made Easy

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Percentages, Fractions, and Decimals are connected. Percentages, fractions, and decimals are all different ways to represent parts of a whole. They can be converted between each other, which is useful for solving many mathematical problems.

We often see phrases like

  • up to 75% off on all items
  • 90% housing loan with low-interest rates
  • 10% to 50% discount advertisements

Examples of Percentages, Fractions, and Decimals

These are some examples of percentages.

Suppose, there are 200 students in a college. Let 80 students remain in college to participate in college extra-curricular activities (ECA). The fraction of students who participated in college ECA can be written as $\frac{80}{100}$, or $\frac{40}{100}$, or $\frac{2}{5}$. We can read it as 80 out of 200 students participated in ECA (or 2 out of 5 participated in ECA). Multiplying this fraction with 100 will convert the fraction to percentages. Therefore, 40% of the students participated in ECA.

By percent means that for every hundred or out of every hundred.

Therefore, a percentage is a fraction whose denominator is always 100. Therefore, a percentage can be converted to a fraction by dividing it by 100. Alternatively, one can change a fraction or a decimal to a percentage by multiplying it by 100. The following figure is about the conversion cycle of percentages to fractions or decimals and vice versa.

Percentages, Fractions, and Decimals

Real-life Examples of Percentages, Fractions, and Decimals

Suppose, you are told that 70% of the students in a class of 50 passed a Mathematics test. How many of them failed?

Number of Students passed the Mathematics test = 70% of 50 = $\frac{70}{100}\times 50 = 35$

Number of students who failed the Mathematics test = $50 – 35 = 15$.

The number of students who failed can be found in an alternative way

\[(100-70)\%\times 50 = \frac{30}{100}\times 50 = 15\]

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Skewness and Measures of Skewness

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If the curve is symmetrical, a deviation below the mean exactly equals the corresponding deviation above the mean. This is called symmetry. Here, we will discuss Skewness and Measures of Skewness.

Skewness is the degree of asymmetry or departure from the symmetry of a distribution. Positive Skewness means when the tail on the right side of the distribution is longer or fatter. The mean and median will be greater than the mode. Negative Skewness is when the tail of the left side of the distribution is longer or fatter than the tail on the right side.

Skewness and Measures of Skewness

Measures of Skewness

Karl Pearson Measures of Relative Skewness

In a symmetrical distribution, the mean, median, and mode coincide. In skewed distributions, these values are pulled apart; the mean tends to be on the same side of the mode as the longer tail. Thus, a measure of the asymmetry is supplied by the difference ($mean – mode$). This can be made dimensionless by dividing by a measure of dispersion (such as SD).

The Karl Pearson measure of relative skewness is
$$\text{SK} = \frac{\text{Mean}-\text{mode}}{SD} =\frac{\overline{x}-\text{mode}}{s}$$
The value of skewness may be either positive or negative.

The empirical formula for skewness (called the second coefficient of skewness) is

$$\text{SK} = \frac{3(\text{mean}-\text{median})}{SD}=\frac{3(\tilde{X}-\text{median})}{s}$$

Bowley Measures of Skewness

In a symmetrical distribution, the quartiles are equidistant from the median ($Q_2-Q_1 = Q_3-Q_2$). If the distribution is not symmetrical, the quartiles will not be equidistant from the median (unless the entire asymmetry is located in the extreme quarters of the data). The Bowley suggested measure of skewness is

$$\text{Quartile Coefficient of SK} = \frac{Q_(2-Q_2)-(Q_2-Q_1)}{Q_3-Q_1}=\frac{Q_2-2Q_2+Q_1}{Q_3-Q_1}$$

This measure is always zero when the quartiles are equidistant from the median and is positive when the upper quartile is farther from the median than the lower quartile. This measure of skewness varies between $+1$ and $-1$.

Moment Coefficient of Skewness

In any symmetrical curve, the sum of odd powers of deviations from the mean will be equal to zero. That is, $m_3=m_5=m_7=\cdots=0$. However, it is not true for asymmetrical distributions. For this reason, a measure of skewness is devised based on $m_3$. That is

\begin{align}
\text{Moment of Coefficient of SK}&= a_3=\frac{m_3}{s^3}=\frac{m_3}{\sqrt{m_2^3}}\\
&=b_1=\frac{m_3^2}{m_2^3}
\end{align}

For perfectly symmetrical curves (normal curves), $a_3$ and $b_1$ are zero.

Skewness ad Measure of Skewness

Real-Life Examples of Skewness

  1. Income Distribution: Income distribution in most countries is right-skewed. A large number of people earn relatively low incomes, while a smaller number earn significantly higher incomes, creating a long tail on the right side of the distribution.
  2. Insurance Claims: Insurance claim amounts are typically right-skewed. Most claims are for smaller amounts, but there are a few very large claims that create a long tail on the right.
  3. Age at Retirement: The age at which people retire is often right-skewed. Most people retire around a certain age, but some continue to work much later in life, creating a long tail on the right.
  4. Test Scores: In some educational settings, test scores can be left-skewed if the test is very easy, with most students scoring high and a few scoring much lower, creating a long tail on the left.
  5. Hospital Stay Duration: The length of hospital stays is often right-skewed. Most patients stay for a short period, but some patients with severe conditions stay much longer, creating a long tail on the right.
  6. House Prices: In many housing markets, the distribution of house prices is right-skewed. There are many houses priced within a certain range, but a few very expensive houses create a long tail on the right.
  7. Web Traffic: The number of visitors to different websites can be highly right-skewed. A few popular sites get a huge number of visitors, while the majority of sites get much less traffic.
  8. Customer Spending: In retail, customer spending can be right-skewed. Most customers spend a small amount, but a few spend a lot, creating a long tail on the right.
  9. The lifespan of Products: The lifespan of certain products can be right-skewed. Most products last for a certain period, but a few last much longer, creating a long tail on the right.
  10. Natural Disasters: The severity of natural disasters, such as earthquakes or hurricanes, can be right-skewed. Most events are of low to moderate severity, but a few are extremely severe, creating a long tail on the right.

FAQs about SKewness

  1. What is skewness?
  2. If a curve is symmetrical then what is the behavior of deviation below and above the mean?
  3. What is Bowley’s Measure of Skewness?
  4. What is Karl Person’s Measure of Relative Skewness?
  5. What is the moment coefficient of skewness?
  6. What is the positive and negative skewness?

Skewness

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