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Statistical Reasoning for everyday life

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Title: Statistical Reasoning for everyday life


1
Statistical Reasoningfor everyday life
  • Intro to Probability and Statistics
  • Mr. Spering Room 113

2
4.3 Measures of Variation
Top of the Muffin to you! ?????
  • Variation
  • Describes how widely data are spread out about
    the center of a distribution.
  • ????How would you expect the variation to differ
    between the running times of theatre movies
    compared to running times for television
    sitcoms????
  • Theatre movie times more variation
  • Television sitcoms less variation usually 30 or
    60 minutes

3
4.3 Measures of Variation
  • How do we investigate variation?
  • Study all of the raw data
  • Range
  • Quartiles
  • Five-number summary (BOXPLOT or BOX-and-WHISKER)
  • Interquartile range
  • Semi-quartile range
  • Percentiles
  • MAD
  • Variance Standard Deviation

4
4.3 Measures of Variation
65th Percentile!
  • Today
  • Semi-quartile range
  • Percentiles
  • MAD
  • Variance Standard Deviation

MAD???
5
4.3 Measures of Variation
  • Semi-quartile range
  • The semi-quartile range is another measure of
    spread. It is calculated as one half the
    difference between the Upper Quartile (often
    called Q3) and the Lower Quartile (Q1). The
    formula for semi-quartile range is
  • (Q3Q1) 2.
  • Since half the values in a distribution lie
    between Q3 and Q1, the semi-quartile range is
    one-half the distance needed to cover half the
    values. In a symmetric distribution, an interval
    stretching from one semi-quartile range below the
    median to one semi-quartile above the median will
    contain one-half of the values. However, this
    will not be true for a skewed distribution.
  • The semi-quartile range is not affected by higher
    values, so it is a good measure of spread to use
    for skewed distributions, but it is rarely used
    for data sets that have normal distributions. In
    the case of a data set with a normal
    distribution, the standard deviation is used
    instead. We will discuss standard deviation
    later.

6
4.3 Measures of Variation
  • EXAMPLE Find the Semi-quartile range of the
    data.
  • Semi-quartile
  • 4.1, 5.2, 5.6, 6.2, 7.2, 7.7, 7.7, 8.5, 9.3, 11.0
  • Q1 5.6
  • Q3 8.5
  • Semi-quartile (8.5 5.6) 2
  • 1.45

(Q3Q1) 2
7
4.3 Measures of Variation
  • Percentiles
  • The nth percentile of a data set is (an estimate)
    of a value separating the bottom values from the
    top (100 n). A data value that lies between
    two percentiles is often said to lie in the lower
    percentile. You can approximate the percentile
    of any data value with the following formulas

8
4.3 Measures of Variation
  • EXAMPLE Percentiles.
  • What percentile is the lowest score, Q1, Q2, Q3,
    and highest score?
  • 4.1, 5.2, 5.6, 6.2, 7.2, 7.7, 7.7, 8.5, 9.3,
    11.0
  • Lowest number 0 percentile
  • Q1 5.6 25th percentile
  • Q2 (7.7 - 7.2)/2 7.45 50th percentile
  • Q3 8.5 75th percentile
  • Highest number 100th percentile

9
4.3 Measures of Variation
  • EXAMPLE Percentiles.
  • What percentile is the 9.3?
  • 4.1, 5.2, 5.6, 6.2, 7.2, 7.7, 7.7, 8.5, 9.3,
    11.0
  • 9.3 is the 9th number out of ten, after the
    numbers are set in ascending order. Therefore,
    it is larger than 9 out of ten numbers, or the
    90th percentile.

Note One quartile is equivalent to 25 percentile
while 1 decile is equal to 10 percentile and 1
quintile is equal to 20 percentile Think about
it P25 Q1, P50 D5 Q2 median value, P75
Q3, P100 D10 Q4, P10 D1, P20 D2, P30
D3, P40 D4, P60 D6, P70 D7, P80 D8, P90
D9
10
4.3 Measures of Variation
  • MAD Mean Absolute Deviation
  • MAD is the mean of the absolute differences
    between the sample mean and the data values.

11
4.3 Measures of Variation
  • Example Find the MAD (Mean Absolute Deviation).
  • DATA 10, 1, 3, 3, 3, 4, 5, 6, 5, 10
  • Mean 5
  • ? 5, 4, 2, 2, 2, 1, 0, 1, 0, 5 22
  • MAD 22/10 2.2

12
4.3 Measures of Variation
  • Variance
  • The variance of a random variable is a measure of
    statistical dispersion/distribution found by
    averaging the squared distance of its possible
    values from the mean. Whereas the mean is a way
    to describe the location of a distribution, the
    variance is a way to capture its scale or degree
    of being spread out. The unit of variance is the
    square of the unit of the original variable.


Variance
13
4.3 Measures of Variation
  • Example Find the Variance.
  • DATA 10, 1, 3, 3, 3, 4, 5, 6, 5, 10
  • Mean 5
  • ? 25, 16, 4, 4, 4, 1, 0, 1, 0, 25
  • Variance (s2) 80/9 8 8/9 8.89

14
4.3 Measures of Variation
  • Standard Deviation
  • Universally accepted as the best measure of
    statistical dispersion/distribution.
  • Standard deviation is developed because there is
    a problem with variances. Recall that the
    deviations were squared. That means that the
    units were also squared. To get the units back
    the same as the original data values, the square
    root must be taken.

15
4.3 Measures of Variation
  • Example Find the Standard Deviation
  • DATA 10, 1, 3, 3, 3, 4, 5, 6, 5, 10
  • Mean 5
  • ? 25, 16, 4, 4, 4, 1, 0, 1, 0, 25
  • Variance (s2) 80/9 8 8/9 8.89
  • Standard Deviation
  • 2.981

16
4.3 Measures of Variation
  • The Range Rule of Thumb
  • The is approximately related to the range
    of distribution by the following
  • We can use this rule of thumb to estimate the low
    and high values
  • low value mean 2 standard deviation
  • high value mean 2 standard deviation
  • The range rule of thumb does not work well when
    low and high values are extreme outliers.
    Therefore, use careful judgment in deciding
    whether the range rule of thumb is applicable.

17
4.3 Measures of Variation
  • The Range Rule of Thumb
  • EXAMPLE
  • The mean score on the mathematics SAT for women
    is 496, and the standard of deviation is 108.
    Use the range rule of thumb to estimate the
    minimum and maximum scores for women on the
    mathematics SAT.
  • low value mean 2 standard deviation
  • 496 (2108) 280 minimum
  • high value mean 2 standard deviation
  • 496 (2108) 712 maximum
  • Is this reasonable?
  • Of course, scores below 280 and above 712 are
    unusual on SATs.

18
4.3 Measures of Variation
  • HOMEWORK
  • Pg 174 3
  • Pg 175 9, 10, and 14
  • Pg 176 24, pg 176 25-27 all (Letters c, d
    only)
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