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bayesian_glm.Rmd
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# 贝叶斯广义线性模型 {#bayesian-glm}
```{r, include=FALSE}
knitr::opts_chunk$set(
echo = TRUE,
warning = FALSE,
message = FALSE,
fig.showtext = TRUE
)
```
```{r, message=FALSE, warning=FALSE}
library(tidyverse)
library(tidybayes)
library(rstan)
library(wesanderson)
rstan_options(auto_write = TRUE)
options(mc.cores = parallel::detectCores())
theme_set(
bayesplot::theme_default() +
ggthemes::theme_tufte() +
theme(plot.background = element_rect(fill = wes_palette("Moonrise2")[3],
color = wes_palette("Moonrise2")[3]))
)
```
## 广义线性模型
广义线性模型必须要明确的三个元素:
1. 响应变量的概率分布(Normal, Binomial, Poisson, Categorical, Multinomial, Poisson, Beta)
2. 预测变量的线性组合
$$
\eta = X \vec{\beta}
$$
3. 连接函数($g(.)$), 将期望值映射到预测变量的线性组合
$$
g(\mu) = \eta
$$
连接函数是可逆的(invertible)。连接函数的逆,将预测变量的线性组合**映射**到响应变量的期望值
$$
\mu = g^{-1}(\eta)
$$
通过值域来看,连接函数的逆,将 $\eta$ 从 $(-\infty, +\infty)$ 转换到特定的范围.
### 连接函数
```{r, echo=FALSE}
knitr::include_graphics(here::here("images", "Link_Functions.png"))
```
### 不同分布对应的函数
```{r, echo=FALSE}
knitr::include_graphics(here::here("images", "distributions_and_link_functions.png"))
```
## 研究生院录取时有性别歧视?
这是美国一所大学研究生院的录取人数。我们想看下是否存在性别歧视?
```{r}
UCBadmit <- readr::read_rds(here::here('demo_data', "UCBadmit.rds")) %>%
mutate(applicant_gender = factor(applicant_gender, levels = c("male", "female")))
UCBadmit
```
我们首先将申请者的性别作为预测变量,建立二项式回归模型如下
$$
\begin{align*}
\text{admit}_i & \sim \operatorname{Binomial}(n_i, p_i) \\
\text{logit}(p_i) & = \alpha_{\text{gender}[i]} \\
\alpha_j & \sim \operatorname{Normal}(0, 1.5),
\end{align*}
$$
这里连接函数`logit()`需要说明一下
$$
\begin{align*}
\text{logit}(p_{i}) &= \log\Big(\frac{p_{i}}{1 - p_{i}}\Big) = \alpha_{\text{gender}[i]}\\
\text{equivalent to,} \quad p_{i} &= \frac{1}{1 + \exp[- \alpha_{\text{gender}[i]}]} \\
& = \frac{\exp(\alpha_{\text{gender}[i]})}{1 + \exp (\alpha_{\text{gender}[i]})} \\
& = \text{inv_logit}(\alpha_{\text{gender}[i]})
\end{align*}
$$
R语言glm函数能够拟合一系列的广义线性模型
```{r}
model_logit <- glm(
cbind(admit, rejection) ~ 0 + applicant_gender,
data = UCBadmit,
family = binomial(link = "logit")
)
summary(model_logit)
```
### Stan 代码
```{r}
stan_program_A <- '
data {
int n;
int admit[n];
int applications[n];
int applicant_gender[n];
}
parameters {
real a[2];
}
transformed parameters {
vector[n] p;
for (i in 1:n) {
p[i] = inv_logit(a[applicant_gender[i]]);
}
}
model {
a ~ normal(0, 1.5);
for (i in 1:n) {
admit[i] ~ binomial(applications[i], p[i]);
}
}
'
stan_data <- UCBadmit %>%
compose_data()
fit01 <- stan(model_code = stan_program_A, data = stan_data)
```
```{r}
fit01
```
```{r}
inv_logit <- function(x) {
exp(x) / (1 + exp(x))
}
fit01 %>%
tidybayes::spread_draws(a[i]) %>%
pivot_wider(
names_from = i,
values_from = a,
names_prefix = "a_"
) %>%
mutate(
diff_a = a_1 - a_2,
diff_p = inv_logit(a_1) - inv_logit(a_2)
) %>%
pivot_longer(contains("diff")) %>%
group_by(name) %>%
tidybayes::mean_qi(value, .width = .89)
```
从这个模型的结果看,男性确实有优势。
- 从 log-odd 度量看,男性录取率高于女性录取率
- 从概率的角度看,男性的录取概率比女性高 12% 到 16%
下面我们来看模型拟合的情况
```{r, fig.width = 5, fig.asp = 0.618}
fit01 %>%
tidybayes::gather_draws(p[i]) %>%
tidybayes::mean_qi(.width = .89) %>%
ungroup() %>%
rename(Estimate = .value) %>%
bind_cols(UCBadmit) %>%
ggplot(aes(x = applicant_gender, y = ratio)) +
geom_point(aes(y = Estimate),
color = wes_palette("Moonrise2")[1],
shape = 1, size = 3
) +
geom_point(color = wes_palette("Moonrise2")[2]) +
geom_line(aes(group = dept),
color = wes_palette("Moonrise2")[2]) +
scale_y_continuous(limits = 0:1) +
facet_grid(. ~ dept) +
labs(x = NULL, y = 'Probability of admission')
```
我们能说存在性别歧视?我们发现一些违反直觉的问题:
- 原始数据中只有学院C和E,女性录取率略低于男性,但模型结果却表明,女性预期的录取概率比男性低14%。
- 同时,我们看到男性和女性申请的院系不一样,以下是各学院男女申请人数的比例。女性更倾向与选择A、B之外的学院,比如F学院,而这些学院申请人数比较多,因而男女录取率都很低,甚至不到10%.
也就说,大多女性选择录取率低的学院,从而拉低了女性整体的录取率。
```{r}
UCBadmit %>%
group_by(dept) %>%
mutate(proportion = applications / sum(applications)) %>%
select(dept, applicant_gender, proportion) %>%
pivot_wider(
names_from = dept,
values_from = proportion
) %>%
mutate(
across(where(is.double), round, digits = 2)
)
```
- 模型没有问题,而是我们的提问(对全体学院,男女平均录取率有什么差别?)是有问题的。
因此,我们的提问要修改为:**在每个院系内部,男女平均录取率的差别是多少?**
### 增加预测变量
增加院系项,也就说一个院系对应一个单独的截距,可以捕获院系之间的录取率差别。
$$
\begin{align*}
\text{admit}_i & \sim \operatorname{Binomial} (n_i, p_i) \\
\text{logit}(p_i) & = \alpha_{\text{gender}[i]} + \delta_{\text{dept}[i]} \\
\alpha_j & \sim \operatorname{Normal} (0, 1.5) \\
\delta_k & \sim \operatorname{Normal} (0, 1.5),
\end{align*}
$$
```{r}
stan_program_B <- '
data {
int n;
int n_dept;
int admit[n];
int applications[n];
int applicant_gender[n];
int dept[n];
}
parameters {
real a[2];
real b[n_dept];
}
transformed parameters {
vector[n] p;
for (i in 1:n) {
p[i] = inv_logit(a[applicant_gender[i]] + b[dept[i]]);
}
}
model {
a ~ normal(0, 1.5);
b ~ normal(0, 1.5);
for (i in 1:n) {
admit[i] ~ binomial(applications[i], p[i]);
}
}
'
stan_data <- UCBadmit %>%
compose_data()
fit02 <- stan(model_code = stan_program_B, data = stan_data)
```
```{r}
fit02
```
```{r}
inv_logit <- function(x) {
exp(x) / (1 + exp(x))
}
fit02 %>%
tidybayes::spread_draws(a[i]) %>%
pivot_wider(
names_from = i,
values_from = a,
names_prefix = "a_"
) %>%
mutate(
diff_a = a_1 - a_2,
diff_p = inv_logit(a_1) - inv_logit(a_2)
) %>%
pivot_longer(contains("diff")) %>%
group_by(name) %>%
tidybayes::mean_qi(value, .width = .89)
```
从第二个模型的结果看,男性没有优势,甚至不如女性。
- 从 log-odd 度量看,男性录取率低于女性录取率
- 从概率的角度看,男性的录取概率比女性低 2%
(增加了一个变量,剧情反转了。**辛普森佯谬**)
```{r, fig.width = 5, fig.asp = 0.618}
fit02 %>%
tidybayes::gather_draws(p[i]) %>%
tidybayes::mean_qi(.width = .89) %>%
ungroup() %>%
rename(Estimate = .value) %>%
bind_cols(UCBadmit) %>%
ggplot(aes(x = applicant_gender, y = ratio)) +
geom_point(aes(y = Estimate),
color = wes_palette("Moonrise2")[1],
shape = 1, size = 3
) +
geom_point(color = wes_palette("Moonrise2")[2]) +
geom_line(aes(group = dept),
color = wes_palette("Moonrise2")[2]) +
scale_y_continuous(limits = 0:1) +
facet_grid(. ~ dept) +
labs(x = NULL, y = 'Probability of admission')
```
从图看出,我们第二个模型能够捕捉到数据大部分特征,但还有改进空间。
## 作业
- 讲性别从模型中去除,然后看看模型结果
- 如果我们假定申请人性别影响**院系选择**和**录取率**,把院系当作中介,建立中介模型
```{r, fig.width = 5, fig.asp = 0.6}
library(ggdag)
dag_coords <-
tibble(name = c("G", "D", "A"),
x = c(1, 2, 3),
y = c(1, 2, 1))
dagify(D ~ G,
A ~ D + G,
coords = dag_coords) %>%
ggplot(aes(x = x, y = y, xend = xend, yend = yend)) +
geom_dag_text(color = wes_palette("Moonrise2")[4], family = "serif") +
geom_dag_edges(edge_color = wes_palette("Moonrise2")[4]) +
scale_x_continuous(NULL, breaks = NULL) +
scale_y_continuous(NULL, breaks = NULL)
```
```{r, echo = F, message = F, warning = F, results = "hide"}
ggplot2::theme_set(ggplot2::theme_grey())
pacman::p_unload(pacman::p_loaded(), character.only = TRUE)
```