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Chi-Squared (?2) Analysis

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Chi-Squared ( 2) Analysis AP Biology Unit 4 What is Chi-Squared? In genetics, you can predict genotypes based on probability (expected results) Chi-squared is a form ... – PowerPoint PPT presentation

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Title: Chi-Squared (?2) Analysis


1
Chi-Squared (?2) Analysis
AP Biology Unit 4
2
What is Chi-Squared?
  • In genetics, you can predict genotypes based on
    probability (expected results)
  • Chi-squared is a form of statistical analysis
    used to compare the actual results (observed)
    with the expected results
  • NOTE ?2 is the name of the whole variable you
    will never take the square root of it or solve
    for ?

3
Chi-squared
  • If the expected and observed (actual) values are
    the same then the ?2 0
  • If the ?2 value is 0 or is small then the data
    fits your hypothesis (the expected values) well.
  • By calculating the ?2 value you determine if
    there is a statistically significant difference
    between the expected and actual values.

4
Step 1 State a null hypothesis
  • Your null hypothesis states that there is no
    difference between the observed and expected
    values.
  • You will either accept or reject your null
    hypothesis based on the Chi squared value that
    you determine.

5
Step 2 Calculating expected and determining
observed values
  • First, determine what your expected and observed
    values are.
  • Observed (Actual) values That should be
    something you get from data usually no
    calculations ?
  • Expected values based on probability
  • Suggestion make a table with the expected and
    actual values

6
Step 1 Example
  • Observed (actual) values Suppose you have 90
    tongue rollers and 10 nonrollers
  • Expected Suppose the parent genotypes were both
    Rr ? using a punnett square, you would expect 75
    tongue rollers, 25 nonrollers
  • This translates to 75 tongue rollers, 25
    nonrollers (since the population you are dealing
    with is 100 individuals)

7
Step 1 Example
  • Table should look like this

Expected Observed (Actual)
Tongue rollers 75 90
Nonrollers 25 10
8
Step 2 Calculating ?2
  • Use the formula to calculated ?2
  • For each different category (genotype or
    phenotype calculate
  • (observed expected)2 / expected
  • Add up all of these values to determine ?2

9
Step 2 Calculating ?2
10
Step 2 Example
  • Using the data from before
  • Tongue rollers
  • (90 75)2 / 75 3
  • Nonrollers
  • (10 25)2 / 25 9
  • ?2 3 9 12

11
Step 3 Determining Degrees of Freedom
  • Degrees of freedom of categories 1
  • Ex. For the example problem, there were two
    categories (tongue rollers and nonrollers) ?
    degrees of freedom 2 1
  • Degrees of freedom 1

12
Step 3 Determining Degrees of Freedom
  • Degrees of freedom (df) refers to the number of
    values that are free to vary after restriction
    has been
  • placed on the data. For instance, if you have
    four numbers with the restriction that their sum
    has to be 50,
  • then three of these numbers can be anything, they
    are free to vary, but the fourth number
    definitely is
  • restricted. For example, the first three numbers
    could be 15, 20, and 5, adding up to 40 then the
    fourth
  • number has to be 10 in order that they sum to 50.
    The degrees of freedom for these values are then
    three.
  • The degrees of freedom here is defined as N - 1,
    the number in the group minus one restriction (4
    - I ).
  • Adapted by Anne F. Maben from "Statistics for the
    Social Sciences" by Vicki Sharp

13
Step 4 Critical Value
  • Using the degrees of freedom, determine the
    critical value using the provided table
  • Df 1 ? Critical value 3.84

14
Step 5 Conclusion
  • If ?2 gt critical value
  • there is a statistically significant difference
    between the actual and expected values.
  • If ?2 lt critical value
  • there is a NOT statistically significant
    difference between the actual and expected values.

15
Step 5 Example
  • ?2 12 gt 3.84
  • There is a statistically significant difference
    between the observed and expected population

16
Chi-squared and Hardy Weinberg
  • Review If the observed (actual) and expected
    genotype frequencies are the same then a
    population is in Hardy Weinberg equilibrium
  • But how close is close enough?
  • Use Chi-squared to figure it out!
  • If there isnt a statistically significant
    difference between the expected and actual
    frequencies, then it is in equilibrium

17
Example
  • Using the example from yesterday

Ferrets Expected Observed (Actual)
BB 0.45 x 164 74 78
Bb 0.44 x 164 72 65
bb 0.11 x 164 18 21
18
Example
  • ?2 Calculation
  • BB (78 74)2 / 74 0.21
  • Bb (72 65)2 / 72 0.68
  • bb (18 21)2 / 18 0.5
  • ?2 0.21 0.68 0.5 1.39
  • Degrees of Freedom 3 1 2
  • Critical value 5.99
  • ?2 lt 5.99 ? there is not a statistically
    significant difference between expected and
    actual values ? population DOES SEEM TO BE in
    Hardy Weinberg Equilibrium (different answer from
    last lecture more accurate)
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