Difference between revisions of "Shapes of distribution"

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(Created page with "Distribution of data can take a wide variety of shapes, and ultimately depends on how data points are distributed along the measurement scale. A general "feel" for the data c...")
 
(Normal (bell-shaped) distribution)
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== Normal (bell-shaped) distribution ==
 
== Normal (bell-shaped) distribution ==
  
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When the collected data tends to hover around a central value, with no bias to the left or the right, the data creates a Normal distribution. 
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This Normal distribution is also referred to as the "Bell Curve" because it resembles a bell like shape.
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When stating that data is normally distributed we are identifying that 50% of the values are less than the mean and that 50% of the values are greater than the mean.  In a normal distribution the mean, median, and mode are equal to one another.
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Examples of data that follow a normal distribution could include blood pressure and scores on a test.
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''contributed by, Scott Trungadi''
  
 
== Skewness ==
 
== Skewness ==

Revision as of 15:44, 23 September 2019

Distribution of data can take a wide variety of shapes, and ultimately depends on how data points are distributed along the measurement scale. A general "feel" for the data can be achieved by examining the uniformity (or lack thereof) of a distribution. In general, the larger the sample size, the more symmetrical the distribution.


Uniform distribution

Normal (bell-shaped) distribution

When the collected data tends to hover around a central value, with no bias to the left or the right, the data creates a Normal distribution. This Normal distribution is also referred to as the "Bell Curve" because it resembles a bell like shape.

When stating that data is normally distributed we are identifying that 50% of the values are less than the mean and that 50% of the values are greater than the mean. In a normal distribution the mean, median, and mode are equal to one another.

Examples of data that follow a normal distribution could include blood pressure and scores on a test.

contributed by, Scott Trungadi

Skewness

Skewed right Skewed left

Acceptable skewness values: -1.000 < skewness < 1.000


Examining the data skewness allows you to see the variability of a data set. Skewness is when a data set does not follow the normal distribution. A normal distribution has a skewness of zero, and will have perfect symmetry. Data that is positively skewed will be skewed to the right and will be a positive number; data that is negatively skewed is skewed to the left of the data mean, and is a negative number. See an example of skewness, below.

"contributed by Cassandra Cosentino"

Skewness.png

Kurtosis

Leptokurtic Platykurtic

Acceptable kurtosis values : -1.000 < kurtosis < 1.000