Hypothesis Testing

Using computer simulation. Based on examples from the infer package. Code for Quiz 13.

Load the R package we will use.

library(tidyverse)
library(infer)
library(skimr)

• Replace all the instances of ???. These are answers on your moodle quiz.

• Run all the individual code chunks to make sure the answers in this file correspond with your quiz answers

• After you check all your code chunks run then you can knit it. It won’t knit until the ??? are replaced

• Save a plot to be your preview plot

Question: t-test

• The data this quiz is a subset of HR
• Look at the variable definitions
• Note that the variables evaluation and salary have been recoded to be represented as words instead of numbers
• Set random seed generator to 123

set.seed(123)

hr_2_tidy.csv is the name of your data subset

• Read it into and assign to hr

• Note: col_types = “fddfff” defines the column types factor-double-double-factor-factor-factor

hr <- read_csv("https://estanny.com/static/week13/data/hr_2_tidy.csv",col_types = "fddfff")

Use the skim to summarize the data in hr

skim(hr)

Table 1: Data summary

Name	hr
Number of rows	500
Number of columns	6
_______________________
Column type frequency:
factor	4
numeric	2
________________________
Group variables	None

Variable type: factor

skim_variable	n_missing	complete_rate	ordered	n_unique	top_counts
gender	0	1	FALSE	2	mal: 256, fem: 244
evaluation	0	1	FALSE	4	bad: 154, fai: 142, goo: 108, ver: 96
salary	0	1	FALSE	6	lev: 95, lev: 94, lev: 87, lev: 85
status	0	1	FALSE	3	fir: 194, pro: 179, ok: 127

Variable type: numeric

skim_variable	n_missing	complete_rate	mean	sd	p0	p25	p50	p75	p100	hist
age	0	1	39.86	11.55	20.3	29.60	40.2	50.1	59.9	▇▇▇▇▇
hours	0	1	49.39	13.15	35.0	37.48	45.6	58.9	79.9	▇▃▂▂▂

• The mean hours worked per week is: 49.4

Q: Is the mean number of hours worked per week 48?

specify that hours is the variable of interest

hr %>% 
  specify(response = hours)

Response: hours (numeric)
# A tibble: 500 x 1
   hours
   <dbl>
 1  78.1
 2  35.1
 3  36.9
 4  38.5
 5  36.1
 6  78.1
 7  76  
 8  35.6
 9  35.6
10  56.8
# … with 490 more rows

hypothesize that the average hours worked is 48

hr %>% 
  specify(response = hours) %>% hypothesize(null = "point", mu =48)

Response: hours (numeric)
Null Hypothesis: point
# A tibble: 500 x 1
   hours
   <dbl>
 1  78.1
 2  35.1
 3  36.9
 4  38.5
 5  36.1
 6  78.1
 7  76  
 8  35.6
 9  35.6
10  56.8
# … with 490 more rows

generate 1000 replicates representing the null hypothesis

 hr %>% specify(response = hours) %>% hypothesize(null = "point", mu = 48) %>% generate(reps = 1000, type = "bootstrap")

Response: hours (numeric)
Null Hypothesis: point
# A tibble: 500,000 x 2
# Groups:   replicate [1,000]
   replicate hours
       <int> <dbl>
 1         1  39.7
 2         1  44.3
 3         1  46.8
 4         1  33.7
 5         1  39.6
 6         1  39.5
 7         1  40.5
 8         1  55.8
 9         1  72.6
10         1  35.7
# … with 499,990 more rows

The output has 500,000 rows

calculate the distribution of statistics from the generated data

• Assign the output null_t_distribution

• Display null_t_distribution

null_t_distribution <- hr %>% specify(response = age) %>% hypothesize(null = "point", mu = 48) %>% generate(reps = 1000, type = "bootstrap") %>% calculate(stat = "t")
null_t_distribution

# A tibble: 1,000 x 2
   replicate     stat
 *     <int>    <dbl>
 1         1  0.144  
 2         2 -1.72   
 3         3  0.404  
 4         4 -1.11   
 5         5  0.00894
 6         6  1.46   
 7         7 -0.905  
 8         8 -0.663  
 9         9  0.291  
10        10  3.09   
# … with 990 more rows

• null_t_distribution has 1000 t-stats

visualize the simulated null distribution

visualize(null_t_distribution)

calculate the statistic from your observed data

• Assign the output observed_t_statistic

• Display observed_t_statistic

observed_t_statistic <- hr %>% specify(response = hours) %>% hypothesize(null = "point", mu = 48) %>% calculate(stat = "t")

get_p_value from the simulated null distribution and the observed statistic

null_t_distribution %>%
  get_p_value(obs_stat = observed_t_statistic , 
      direction = "two-sided") 

# A tibble: 1 x 1
  p_value
    <dbl>
1   0.014

shade_p_value on the simulated null distribution

null_t_distribution %>%
  visualize() + 
  shade_p_value(obs_stat = observed_t_statistic, direction = "two-sided")

If the p-value < 0.05? yes

Does your analysis support the null hypothesis that the true mean number of hours worked was 48? no

Question: 2 sample t-test

SEE QUIZ is the name of your data subset

• Read it into and assign to hr_2

• Note: col_types = “fddfff” defines the column types factor-double-double-factor-factor-factor

 hr_2 <- read_csv("https://estanny.com/static/week13/data/hr_1_tidy.csv", col_types = "fddfff")

Q: Is the average number of hours worked the same for both genders?

use skim to summarize the data in hr_2 by gender

hr_2 %>% 
  group_by(gender) %>% 
  skim()

Table 2: Data summary

Name	Piped data
Number of rows	500
Number of columns	6
_______________________
Column type frequency:
factor	3
numeric	2
________________________
Group variables	gender

Variable type: factor

skim_variable	gender	n_missing	complete_rate	ordered	n_unique	top_counts
evaluation	female	0	1	FALSE	4	fai: 81, bad: 71, ver: 57, goo: 51
evaluation	male	0	1	FALSE	4	bad: 82, fai: 61, goo: 55, ver: 42
salary	female	0	1	FALSE	6	lev: 54, lev: 50, lev: 44, lev: 41
salary	male	0	1	FALSE	6	lev: 52, lev: 47, lev: 46, lev: 39
status	female	0	1	FALSE	3	fir: 96, pro: 87, ok: 77
status	male	0	1	FALSE	3	fir: 89, ok: 76, pro: 75

Variable type: numeric

skim_variable	gender	n_missing	complete_rate	mean	sd	p0	p25	p50	p75	p100	hist
age	female	0	1	41.78	11.50	20.5	32.15	42.35	51.62	59.9	▆▅▇▆▇
age	male	0	1	39.32	11.55	20.2	28.70	38.55	49.52	59.7	▇▇▆▇▆
hours	female	0	1	50.32	13.23	35.0	38.38	47.80	60.40	79.7	▇▃▃▂▂
hours	male	0	1	48.24	12.95	35.0	37.00	42.40	57.00	78.1	▇▂▂▁▂

• Females worked an average of 50.3 hours per week

• Males worked an average of 48.2 hours per week

Use geom_boxplot to plot distributions of hours worked by gender

hr_2 %>% 
  ggplot(aes(x = gender, y = hours)) + 
  geom_boxplot()

specify the variables of interest are hours and gender

hr_2 %>%
  specify(response = hours, explanatory = gender)

Response: hours (numeric)
Explanatory: gender (factor)
# A tibble: 500 x 2
   hours gender
   <dbl> <fct> 
 1  36.5 female
 2  55.8 female
 3  35   male  
 4  52   female
 5  35.1 male  
 6  36.3 female
 7  40.1 female
 8  42.7 female
 9  66.6 male  
10  35.5 male  
# … with 490 more rows

hypothesize that the number of hours worked and gender are independent

hr_2 %>%
  specify(response = hours, explanatory = gender) %>%
  hypothesize(null = "independence")

Response: hours (numeric)
Explanatory: gender (factor)
Null Hypothesis: independence
# A tibble: 500 x 2
   hours gender
   <dbl> <fct> 
 1  36.5 female
 2  55.8 female
 3  35   male  
 4  52   female
 5  35.1 male  
 6  36.3 female
 7  40.1 female
 8  42.7 female
 9  66.6 male  
10  35.5 male  
# … with 490 more rows

generate 1000 replicates representing the null hypothesis

hr_2 %>% specify(response = hours, explanatory = gender) %>% hypothesize(null = "independence") %>% generate(reps = 1000, type = "permute")

Response: hours (numeric)
Explanatory: gender (factor)
Null Hypothesis: independence
# A tibble: 500,000 x 3
# Groups:   replicate [1,000]
   hours gender replicate
   <dbl> <fct>      <int>
 1  36.4 female         1
 2  35.8 female         1
 3  35.6 male           1
 4  39.6 female         1
 5  35.8 male           1
 6  55.8 female         1
 7  63.8 female         1
 8  40.3 female         1
 9  56.5 male           1
10  50.1 male           1
# … with 499,990 more rows

The output has 500,000 rows

calculate the distribution of statistics from the generated data

• Assign the output null_distribution_2_sample_permute

• Display null_distribution_2_sample_permute

null_distribution_2_sample_permute <- hr_2 %>% specify(response = hours, explanatory = gender) %>% hypothesize(null = "independence") %>% generate(reps = 1000, type = "permute") %>% calculate(stat = "F", order = c("female", "male"))
null_distribution_2_sample_permute

# A tibble: 1,000 x 2
   replicate    stat
 *     <int>   <dbl>
 1         1  0.0433
 2         2  0.107 
 3         3  5.23  
 4         4  0.278 
 5         5  2.54  
 6         6  0.630 
 7         7  1.53  
 8         8 11.0   
 9         9  0.267 
10        10  0.901 
# … with 990 more rows

• null_t_distribution has 1000 t-stats

visualize the simulated null distribution

visualize(null_distribution_2_sample_permute)

calculate the statistic from your observed data

• Assign the output observed_t_2_sample_stat

• Display observed_t_2_sample_stat

observed_t_2_sample_stat <- hr_2 %>% specify(response = hours, explanatory = gender) %>% calculate(stat = "t", order = c("female", "male"))
observed_t_2_sample_stat

# A tibble: 1 x 1
   stat
  <dbl>
1  1.78

get_p_value from the simulated null distribution and the observed statistic

null_t_distribution %>% 
 get_p_value (obs_stat = observed_t_2_sample_stat , direction = "two-sided")

# A tibble: 1 x 1
  p_value
    <dbl>
1   0.086

shade_p_value on the simulated null distribution

null_t_distribution %>% 
  visualize() + 
  shade_p_value(obs_stat = observed_t_2_sample_stat, direction = "two-sided")

If the p-value < 0.05? no

Does your analysis support the null hypothesis that the true mean number of hours worked by female and male employees was the same? ??? yes

Question: ANOVA

hr_2_tidy.csv is the name of your data subset

• Read it into and assign to hr_anova

• Note: col_types = “fddfff” defines the column types factor-double-double-factor-factor-factor

hr_anova <- read_csv("https://estanny.com/static/week13/data/hr_2_tidy.csv", col_types = "fddfff")

Q: Is the average number of hours worked the same for all three status (fired, ok and promoted) ?

use skim to summarize the data in hr_anova by status

hr_anova %>%
  group_by(status) %>%
  skim()

Table 3: Data summary

Name	Piped data
Number of rows	500
Number of columns	6
_______________________
Column type frequency:
factor	3
numeric	2
________________________
Group variables	status

Variable type: factor

skim_variable	status	n_missing	complete_rate	ordered	n_unique	top_counts
gender	promoted	0	1	FALSE	2	mal: 90, fem: 89
gender	fired	0	1	FALSE	2	fem: 101, mal: 93
gender	ok	0	1	FALSE	2	mal: 73, fem: 54
evaluation	promoted	0	1	FALSE	4	goo: 70, ver: 62, fai: 24, bad: 23
evaluation	fired	0	1	FALSE	4	bad: 78, fai: 72, goo: 25, ver: 19
evaluation	ok	0	1	FALSE	4	bad: 53, fai: 46, ver: 15, goo: 13
salary	promoted	0	1	FALSE	6	lev: 42, lev: 42, lev: 39, lev: 34
salary	fired	0	1	FALSE	6	lev: 54, lev: 44, lev: 34, lev: 24
salary	ok	0	1	FALSE	6	lev: 32, lev: 31, lev: 26, lev: 19

Variable type: numeric

skim_variable	status	n_missing	complete_rate	mean	sd	p0	p25	p50	p75	p100	hist
age	promoted	0	1	40.63	11.25	20.4	30.75	41.10	50.25	59.9	▆▇▇▇▇
age	fired	0	1	40.03	11.53	20.3	29.45	40.40	50.08	59.9	▇▅▇▆▆
age	ok	0	1	38.50	11.98	20.3	28.15	38.70	49.45	59.9	▇▆▅▅▆
hours	promoted	0	1	59.21	12.66	35.0	49.75	58.90	70.65	79.9	▅▆▇▇▇
hours	fired	0	1	41.67	8.37	35.0	36.10	38.45	43.40	77.7	▇▂▁▁▁
hours	ok	0	1	47.35	10.86	35.0	37.10	45.70	54.50	78.9	▇▅▃▂▁

• Employees that were fired worked an average of 2 hours per week

• Employees that were ok worked an average of 3 hours per week

• Employees that were promoted worked an average of 1 hours per week

Use geom_boxplot to plot distributions of hours worked by status

hr_anova %>% 
  ggplot(aes(x = status, y = hours)) +
  geom_boxplot()

specify the variables of interest are hours and status

hr_anova %>% 
  specify(response = hours, explanatory = status)

Response: hours (numeric)
Explanatory: status (factor)
# A tibble: 500 x 2
   hours status  
   <dbl> <fct>   
 1  78.1 promoted
 2  35.1 fired   
 3  36.9 fired   
 4  38.5 fired   
 5  36.1 fired   
 6  78.1 promoted
 7  76   promoted
 8  35.6 fired   
 9  35.6 ok      
10  56.8 promoted
# … with 490 more rows

hypothesize that the number of hours worked and status are independent

hr_anova %>% 
  specify(response = hours, explanatory = status) %>% hypothesize(null="independence")

Response: hours (numeric)
Explanatory: status (factor)
Null Hypothesis: independence
# A tibble: 500 x 2
   hours status  
   <dbl> <fct>   
 1  78.1 promoted
 2  35.1 fired   
 3  36.9 fired   
 4  38.5 fired   
 5  36.1 fired   
 6  78.1 promoted
 7  76   promoted
 8  35.6 fired   
 9  35.6 ok      
10  56.8 promoted
# … with 490 more rows

generate 1000 replicates representing the null hypothesis

hr_anova %>% specify(response = hours, explanatory = status) %>% hypothesize(null = "independence") %>% generate(reps = 1000, type = "permute")

Response: hours (numeric)
Explanatory: status (factor)
Null Hypothesis: independence
# A tibble: 500,000 x 3
# Groups:   replicate [1,000]
   hours status   replicate
   <dbl> <fct>        <int>
 1  41.9 promoted         1
 2  36.7 fired            1
 3  35   fired            1
 4  58.9 fired            1
 5  36.1 fired            1
 6  39.4 promoted         1
 7  54.3 promoted         1
 8  59.2 fired            1
 9  40.2 ok               1
10  35.3 promoted         1
# … with 499,990 more rows

The output has 500,000 rows

calculate the distribution of statistics from the generated data

• Assign the output null_distribution_anova

• Display null_distribution_anova

null_distribution_anova <- hr_anova %>% specify(response = hours, explanatory = gender) %>% hypothesize(null = "independence") %>% generate(reps = 1000, type = "permute") %>%  calculate(stat = "F")

null_distribution_anova

# A tibble: 1,000 x 2
   replicate       stat
 *     <int>      <dbl>
 1         1 0.309     
 2         2 0.854     
 3         3 0.00000101
 4         4 0.288     
 5         5 4.26      
 6         6 1.80      
 7         7 0.381     
 8         8 1.40      
 9         9 1.39      
10        10 0.398     
# … with 990 more rows

• null_distribution_anova has 1000 F-stats

visualize the simulated null distribution

  visualize(null_distribution_anova)

calculate the statistic from your observed data

• Assign the output observed_f_sample_stat

• Display observed_f_sample_stat

observed_f_sample_stat <- hr_anova %>% 
  specify(response = hours, explanatory = status) %>% calculate(stat = "F")
observed_f_sample_stat

# A tibble: 1 x 1
   stat
  <dbl>
1  128.

get_p_value from the simulated null distribution and the observed statistic

null_distribution_anova %>% 
  get_p_value(obs_stat = observed_f_sample_stat, direction = "greater")

# A tibble: 1 x 1
  p_value
    <dbl>
1       0

shade_p_value on the simulated null distribution

null_t_distribution %>% 
  visualize() + 
  shade_p_value (obs_stat = observed_f_sample_stat,direction = "greater")

If the p-value < 0.05? yes

Does your analysis support the null hypothesis that the true means of the number of hours worked for those that were “fired”, “ok” and “promoted” were the same? no