Ch.2.1: Frequency Distributions & Graphs
What are some benefits of representing data sets using frequency distributions?
Organizing the data into a frequency distribution can make patterns within the data more evident.
Why should the number of classes in a frequency distribution be between 5 and 20?
If the number of classes in a frequency distribution is not between 5 and 20, it may be difficult to detect any patterns.
relative frequency histogram
frequency histogram that measures *relative* frequencies in the y scale, rather than frequencies (x scale = classes, y scale = relative frequencies in % or 0.0)
range
the difference between the maximum and minimum data entries
class width
the distance between lower OR upper limits of consecutive classes
upper class limit
the greatest number that can belong to the class
lower class limit
the least number that can belong to the class
class boundaries
the numbers that separate classes *without* forming gaps between them
relative frequency
the portion OR percentage of the data that falls in a class (class frequency divided by sample size)
cumulative frequency
the sum of the frequencies of a class and all previous classes
midpoint
the sum of the lower and upper limits of a class, divided by two (the average of the class)
What are some benefits of using graphs of frequency distributions?
It can be easier to identify patterns of a data set by looking at a graph of the frequency distribution.
frequency histogram
a bar graph that represents the frequency distribution of a data set (x scale = classes, y scale = frequencies of class)
cumulative frequency graph (*ogive*)
a line graph that displays the cumulative frequency of each class at its upper class boundary (x scale = upper boundaries, y scale = cumulative frequencies)
frequency polygon
a line graph that emphasizes the continuous change in frequences
frequency distribution
a table that shows *classes* (intervals) of data entries with a count of the number of entries in each class
