In this episode, Ellis Hughes and I use the {DT} package within a {shiny} app and scrape data from hockey-reference.com. We show how you can build a shiny web-app that allows you to insert an html link into the data table so the user can link directly out to the original website if they want to obtain extra data from the source itself.
To access our code, CLICK HERE.
To watch our screen cast, CLICK HERE.
Ellis Hughes and I have been working on some advanced shiny tutorials. This week, we show how you can dynamically link to a webpage via your shiny server, have the server scrape the web page for the defined user query and then return the results back to them. We do this using NHL data provided by the folks at www.hockey-reference.com.
To watch our screen cast, CLICK HERE.
To access our code, CLICK HERE.
We’ve built up a number of simulations over the 7 articles in this series. The last few articles have been looking at linear regression and simulating different intricacies in the data that allow us to explore model assumptions. To end this series, we will now extend the linear model to a mixed model. We will start by building a linear regression model and go through the steps of simulation to build up the hierarchical structure of the data.
For those interesting here are the previous 7 articles in this series:
As always, complete code for this article is available on my GitHub page.
Side Note: This is a very code heavy article as the goal is to show not only simulations of data and models but how to extract the model parameters from the list of simulations. As such, this a rather long article with minimal interpretation of the models.
First a linear model
Our data will look at training load for 10 players in two different positions, Forwards (F) and Mids (M). The Forwards will be simulated to have less training load than the Mids and we will add some random error around the difference in these group means. We will simulate this as a linaer model where b0 represents the model intercept and is the mean value for Forwards and b1 represents the coefficient for when the group is Mids.
library(tidyverse)
library(broom)
library(lme4)
theme_set(theme_light())
## Model Parameters
n_positions <- 2
n_players <- 10
b0 <- 80
b1 <- 20
sigma <- 10
## Simulate
set.seed(300)
pos <- rep(c("M", "F"), each = n_players)
player_id <- rep(1:10, times = 2)
model_error <- rnorm(n = n_positions*n_players, mean = 0, sd = sigma)
training_load <- b0 + b1 * (pos == "M") + model_error
d <- data.frame(pos, player_id, training_load)
d
Calculate some summary statistics
d %>%
ggplot(aes(x = pos, y = training_load)) +
geom_boxplot()
d %>%
group_by(pos) %>%
summarize(N = n(),
avg = mean(training_load),
sd = sd(training_load)) %>%
mutate(se = sd / sqrt(N)) %>%
knitr::kable()
Build a linear model
fit <- lm(training_load ~ pos, data = d) summary(fit)
Now, we wrap all the steps in a function so that we can use replicate() to create thousands of simulations or to change parameters of our simulation. The end result of the function is going to be the linear regression model.
sim_func <- function(n_positions = 2, n_players = 10, b0 = 80, b1 = 20, sigma = 10){
## simulate data
pos <- rep(c("M", "F"), each = n_players)
player_id <- rep(1:10, times = 2)
model_error <- rnorm(n = n_positions*n_players, mean = 0, sd = sigma)
training_load <- b0 + b1 * (pos == "M") + model_error
## store in data frame
d <- data.frame(pos, player_id, training_load)
## construct linear model
fit <- lm(training_load ~ pos, data = d)
summary(fit)
}
Try the function out with the default parameters
sim_func()
Use replicate() to create many simulations.
Doing this simulation once doesn’t help us. We want to be able to do this thousands of times. All of the articles in this series have used for() loops up until this point. But, if you recall the first article in the series where I laid out several helpful functions for coding simulations, I showed an example of the replicate() function, which will take a function and run it’s result for as many times as you specify. I found this function while I was working through the simulation chapter of Gelman et al’s book, Regression and Other Stories. I think in cases like a mixed model simulation, where you can have many layers and complexities to the data, writing a simple function and then replicating it thousands of times is much easier to debug and much cleaner for others to read than having a bunch of nested for() loops.
Technical Note: We specify the argument simplify = FALSE so that the results are returned in a list format. This makes more sense since the results are the regression summary results and not a data frame.
team_training <- replicate(n = 1000,
sim_func(),
simplify = FALSE)
Coefficient Results
team_training %>%
map_df(tidy) %>%
select(term, estimate) %>%
ggplot(aes(x = estimate, fill = term)) +
geom_density() +
facet_wrap(~term, scales = "free_x")
team_training %>%
map_df(tidy) %>%
select(term, estimate) %>%
group_by(term) %>%
summarize(avg = mean(estimate),
SD = sd(estimate))
Compare the simulated results to the results of the original model fit.
tidy(fit)
Model fit parameters
team_training %>%
map_df(glance) %>%
select(adj.r.squared, sigma) %>%
summarize(across(.cols = everything(),
~mean(.x)))
Compare these results to the original fit
fit %>% glance()
Mixed Model 1
Now that we have the general frame work for building a simulation function and using replicate() we will to build a mixed model simulation.
Above we had a team with two positions groups and individual players nested within those position groups. In this mixed model, we will add a second team so that we can explore hierarchical data.
We will simulate data from 3 teams, each with 2 positions (Forward & Mid). This is a pretty simple mixed model. We will build a more complex one after we get a handle on the code below.
## Model Parameters
n_teams <- 3
n_positions <- 2
n_players <- 10
team1_fwd_avg <- 130
team1_fwd_sd <- 15
team1_mid_avg <- 100
team1_mid_sd <- 5
team2_fwd_avg <- 150
team2_fwd_sd <- 20
team2_mid_avg <- 90
team2_mid_sd <- 10
team3_fwd_avg <- 180
team3_fwd_sd <- 15
team3_mid_avg <- 150
team3_mid_sd <- 15
## Simulated data frame
team <- rep(c("Team1","Team2", "Team3"), each = n_players * n_positions)
pos <- c(rep(c("M", "F"), each = n_players), rep(c("M", "F"), each = n_players), rep(c("M", "F"), each = n_players))
player_id <- as.factor(round(seq(from = 100, to = 300, length = length(team)), 0))
d <- data.frame(team, pos, player_id) d %>%
head()
# simulate training loads
set.seed(555)
training_load <- c(rnorm(n = n_players, mean = team1_mid_avg, sd = team1_mid_sd), rnorm(n = n_players, mean = team1_fwd_avg, sd = team1_fwd_sd), rnorm(n = n_players, mean = team2_mid_avg, sd = team2_mid_sd), rnorm(n = n_players, mean = team2_fwd_avg, sd = team2_fwd_sd), rnorm(n = n_players, mean = team3_mid_avg, sd = team3_mid_sd), rnorm(n = n_players, mean = team3_fwd_avg, sd = team3_fwd_sd)) d ,- d %>%
bind_cols(training_load = training_load)
d %>%
head()
Calculate summary statistics
## Average training load by team
d %>%
group_by(team) %>%
summarize(avg = mean(training_load),
SD = sd(training_load))
## Average training load by pos
d %>%
group_by(pos) %>%
summarize(avg = mean(training_load),
SD = sd(training_load))
## Average training load by team & position
d %>%
group_by(team, pos) %>%
summarize(avg = mean(training_load),
SD = sd(training_load)) %>%
arrange(pos)
## Plot
d %>%
ggplot(aes(x = training_load, fill = team)) +
geom_density(alpha = 0.5) +
facet_wrap(~pos)
Construct the mixed model and evaluate the outputs
## Mixed Model fit_lmer <- lmer(training_load ~ pos + (1 |team), data = d) summary(fit_lmer) coef(fit_lmer) fixef(fit_lmer) ranef(fit_lmer) sigma(fit_lmer) hist(residuals(fit_lmer))
Write a mixed model function
sim_func_lmer <- function(n_teams = 3,
n_positions = 2,
n_players = 10,
team1_fwd_avg = 130,
team1_fwd_sd = 15,
team1_mid_avg = 100,
team1_mid_sd = 5,
team2_fwd_avg = 150,
team2_fwd_sd = 20,
team2_mid_avg = 90,
team2_mid_sd = 10,
team3_fwd_avg = 180,
team3_fwd_sd = 15,
team3_mid_avg = 150,
team3_mid_sd = 15){
## Simulated data frame
team <- rep(c("Team1","Team2", "Team3"), each = n_players * n_positions)
pos <- c(rep(c("M", "F"), each = n_players), rep(c("M", "F"), each = n_players), rep(c("M", "F"), each = n_players))
player_id <- as.factor(round(seq(from = 100, to = 300, length = length(team)), 0))
d <- data.frame(team, pos, player_id)
# simulate training loads
training_load <- c(rnorm(n = n_players, mean = team1_mid_avg, sd = team1_mid_sd),
rnorm(n = n_players, mean = team1_fwd_avg, sd = team1_fwd_sd),
rnorm(n = n_players, mean = team2_mid_avg, sd = team2_mid_sd),
rnorm(n = n_players, mean = team2_fwd_avg, sd = team2_fwd_sd),
rnorm(n = n_players, mean = team3_mid_avg, sd = team3_mid_sd),
rnorm(n = n_players, mean = team3_fwd_avg, sd = team3_fwd_sd))
## construct the mixed model
fit_lmer <- lmer(training_load ~ pos + (1 |team), data = d)
summary(fit_lmer)
}
Try out the function
sim_func_lmer()
Now use replicate() and create 1000 simulations of the model and look at the first model in the list
team_training_lmer <- replicate(n = 1000,
sim_func_lmer(),
simplify = FALSE)
## look at the first model in the list
team_training_lmer[[1]]$coefficient
Store the coefficient results of the 1000 simulations in a data frame, create plots of the model coefficients, and compare the results of the simulation to the original mixed model.
lmer_coef <- matrix(NA, ncol = 5, nrow = length(team_training_lmer))
colnames(lmer_coef) <- c("intercept", "intercept_se", "posM", "posM_se", 'model_sigma')
for(i in 1:length(team_training_lmer)){
lmer_coef[i, 1] <- team_training_lmer[[i]]$coefficients[1]
lmer_coef[i, 2] <- team_training_lmer[[i]]$coefficients[3]
lmer_coef[i, 3] <- team_training_lmer[[i]]$coefficients[2]
lmer_coef[i, 4] <- team_training_lmer[[i]]$coefficients[4]
lmer_coef[i, 5] <- team_training_lmer[[i]]$sigma
}
lmer_coef <- as.data.frame(lmer_coef) head(lmer_coef) ## Plot the coefficient for position lmer_coef %>%
ggplot(aes(x = posM)) +
geom_density(fill = "palegreen")
## Summarize the coefficients and their standard errors for the simulations
lmer_coef %>%
summarize(across(.cols = everything(),
~mean(.x)))
## compare to the original model
broom.mixed::tidy(fit_lmer)
sigma(fit_lmer)
Extract the random effects for the intercept and the residual for each of the simulated models
ranef_sim <- matrix(NA, ncol = 2, nrow = length(team_training_lmer))
colnames(ranef_sim) <- c("intercept_sd", "residual_sd")
for(i in 1:length(team_training_lmer)){
ranef_sim[i, 1] <- team_training_lmer[[i]]$varcor %>% as.data.frame() %>% select(sdcor) %>% slice(1) %>% pull(sdcor)
ranef_sim[i, 2] <- team_training_lmer[[i]]$varcor %>% as.data.frame() %>% select(sdcor) %>% slice(2) %>% pull(sdcor)
}
ranef_sim <- as.data.frame(ranef_sim) head(ranef_sim) ## Summarize the results ranef_sim %>%
summarize(across(.cols = everything(),
~mean(.x)))
## Compare with the original model
VarCorr(fit_lmer)
Mixed Model 2
Above was a pretty simple model, just to get our feet wet. Let’s create a more complicated model. Usually in sport and exercise science we have repeated measures of individuals. Often, researchers will set the individual players as random effects with the fixed effects being the component that the researcher is attempting to make an inference about.
In this example, we will set up a team of 12 players with three positions (4 players per position): Forward, Mid, Defender. The aim is to explore the training load differences between position groups while accounting for repeated observations of individuals (in this case, each player will have 20 training sessions). Similar to our first regression model, we will build a data frame of everything we need and then calculate the outcome variable (training load) with a regression model using parameters that we specify. To make this work, we will need to specific an intercept and slope for the position group and an intercept and slope for the individual players as well as a model sigma value. Once we’ve done that, we will fit a mixed model, write a function, and then create 1000 simulations.
## Set up the data frame
n_pos <- 3
n_players <- 12
n_obs <- 20
players <- as.factor(round(seq(from = 100, to = 300, length = n_players), 0))
dat <- data.frame( player_id = rep(players, each = n_obs), pos = rep(c("Fwd", "Mid", "Def"), each = n_players/n_pos * n_obs), training_day = rep(1:n_obs, times = n_players) ) dat %>%
head()
## Create model parameters
# NOTE: Defender will be the intercept
set.seed(6687)
pos_intercept <- 150
posF_coef <- 170
posM_coef <- -70
individual_intercept <- 50
individual_slope <- 10
sigma <- 10
model_error <- rnorm(n = nrow(dat), mean = 0, sd = sigma)
## we will also create some individual player variance
individual_player_variance <- c()
for(i in players){
individual_player_variance[i] <- rnorm(n = 1,
mean = runif(min = 2, max = 10, n = 1),
sd = runif(min = 2, max = 5, n = 1))
}
individual_player_variance <- rep(individual_player_variance, each = n_obs)
dat$training_load <- pos_intercept + posF_coef * (dat$pos == "Fwd") + posM_coef * (dat$pos == "Mid") + individual_intercept + individual_slope * individual_player_variance + model_error dat %>%
head()
Calculate summary stats
## Average training load by pos
dat %>%
group_by(pos) %>%
summarize(avg = mean(training_load),
SD = sd(training_load))
## Plot
dat %>%
ggplot(aes(x = training_load, fill = pos)) +
geom_density(alpha = 0.5)
Construct the mixed model and evaluate the output
## Mixed Model fit_lmer_pos <- lmer(training_load ~ pos + (1 | player_id), data = dat) summary(fit_lmer_pos) coef(fit_lmer_pos) fixef(fit_lmer_pos) ranef(fit_lmer_pos) sigma(fit_lmer_pos) hist(residuals(fit_lmer_pos))
Create a function for the simulation
sim_func_lmer2 <- function(n_pos = 3,
n_players = 12,
n_obs = 20,
pos_intercept = 150,
posF_coef = 170,
posM_coef = -70,
individual_intercept = 50,
individual_slope = 10,
sigma = 10){
players <- as.factor(round(seq(from = 100, to = 300, length = n_players), 0))
dat <- data.frame(
player_id = rep(players, each = n_obs),
pos = rep(c("Fwd", "Mid", "Def"), each = n_players/n_pos * n_obs),
training_day = rep(1:n_obs, times = n_players)
)
model_error <- rnorm(n = nrow(dat), mean = 0, sd = sigma)
individual_player_variance <- c()
for(i in players){
individual_player_variance[i] <- rnorm(n = 1,
mean = runif(min = 2, max = 10, n = 1),
sd = runif(min = 2, max = 5, n = 1))
}
individual_player_variance <- rep(individual_player_variance, each = n_obs)
dat$training_load <- pos_intercept + posF_coef * (dat$pos == "Fwd") + posM_coef * (dat$pos == "Mid") + individual_intercept + individual_slope * individual_player_variance + model_error
fit_lmer_pos <- lmer(training_load ~ pos + (1 | player_id), data = dat)
summary(fit_lmer_pos)
}
Now use `replicate()` and create 1000 simulations of the model and look at the first model in the list.
player_training_lmer <- replicate(n = 1000,
sim_func_lmer2(),
simplify = FALSE)
## look at the first model in the list
player_training_lmer[[1]]$coefficient
Store the coefficient results from the simulations, summarize them, and compare them to the original mixed model.
lmer_player_coef <- matrix(NA, ncol = 7, nrow = length(player_training_lmer))
colnames(lmer_player_coef) <- c("intercept", "intercept_se","posFwd", "posFwd_se", "posMid", "posMid_se", 'model_sigma')
for(i in 1:length(player_training_lmer)){
lmer_player_coef[i, 1] <- player_training_lmer[[i]]$coefficients[1]
lmer_player_coef[i, 2] <- player_training_lmer[[i]]$coefficients[4]
lmer_player_coef[i, 3] <- player_training_lmer[[i]]$coefficients[2]
lmer_player_coef[i, 4] <- player_training_lmer[[i]]$coefficients[5]
lmer_player_coef[i, 5] <- player_training_lmer[[i]]$coefficients[3]
lmer_player_coef[i, 6] <- player_training_lmer[[i]]$coefficients[6]
lmer_player_coef[i, 7] <- player_training_lmer[[i]]$sigma
}
lmer_player_coef <- as.data.frame(lmer_player_coef) head(lmer_player_coef) ## Plot the coefficient for position lmer_player_coef %>%
ggplot(aes(x = posFwd)) +
geom_density(fill = "palegreen")
lmer_player_coef %>%
ggplot(aes(x = posMid)) +
geom_density(fill = "palegreen")
## Summarize the coefficients and their standard errors for the simulations
lmer_player_coef %>%
summarize(across(.cols = everything(),
~mean(.x)))
## compare to the original model
broom.mixed::tidy(fit_lmer_pos)
sigma(fit_lmer_pos)
Extract the random effects for the intercept and the residual for each of the simulated models.
ranef_sim_player <- matrix(NA, ncol = 2, nrow = length(player_training_lmer))
colnames(ranef_sim_player) <- c("player_sd", "residual_sd")
for(i in 1:length(player_training_lmer)){
ranef_sim_player[i, 1] <- player_training_lmer[[i]]$varcor %>% as.data.frame() %>% select(sdcor) %>% slice(1) %>% pull(sdcor)
ranef_sim_player[i, 2] <- player_training_lmer[[i]]$varcor %>% as.data.frame() %>% select(sdcor) %>% slice(2) %>% pull(sdcor)
}
ranef_sim_player <- as.data.frame(ranef_sim_player) head(ranef_sim_player) ## Summarize the results ranef_sim_player %>%
summarize(across(.cols = everything(),
~mean(.x)))
## Compare with the original model
VarCorr(fit_lmer_pos)
Wrapping Up
Mixed models can get really complicated and have a lot of layers to them. For example, we could make this a multivariable model with independent variables that have some level of correlation with each other. We could also add some level of autocorrelation for each player’s observations. There are also a number of different ways that you can construct these types of simulations. The two approaches used here are just dipping their toes in. Perhaps in future articles I’ll put together code for more complex mixed models.
All of the code for this article and the other 7 articles in this series are available on my GitHub page.
Introduction
I was talking with a friend the other day who was telling me about his brother, who leads guided deer hunts in Wyoming. Typically, clients will come out for a hunt over several days and rely on him to guide them to areas of the forest where there is a high probability of seeing deer. Of course, nothing is guaranteed! It’s entirely possible to go the length of the trip and not see any deer at all. So, my friend was explaining that his brother is very good at constantly keeping an eye on the environment and his surroundings and creating a mental map in his head about the areas that will maximize his clients chances of finding deer. (There is probably an actual name for this skill, but I’m not sure what it is).
This is an interesting problem and reminds me of Bayesian Search Theory, which is used to help locate objects based on prior knowledge/information and the probability of seeing the object within a specific area given it would actually be there. This approach was most recently popularized for its use in the search for the wreckage of Malaysian Airlines Flight 370.
Let’s walk through an example of how Bayesian Search Theory works.
Setting up the search grid
Let’s say our deer guide has a map that he has broken up into a 4×4 grid of squares. He places prior probabilities of seeing a deer in each region given what he knows about the terrain (e.g., areas with water and deer food will have a higher probability of deer activity).
His priors grid looks like this:
library(tidyverse)
theme_set(theme_light())
# priors for each square region looks like this
matrix(data = c(0.01, 0.02, 0.01, 0.1, 0.1, 0.03, 0.03, 0.03,
0.2, 0.2, 0.17, 0.1, 0.01, 0.01, 0.02, 0.01),
byrow = TRUE,
nrow = 4, ncol = 4) %>%
as.data.frame() %>%
setNames(c("1", "2", "3", "4")) %>%
pivot_longer(cols = everything(),
names_to = 'x_coord') %>%
mutate(y_coord = rep(1:4, each = 4)) %>%
relocate(y_coord, .before = x_coord) %>%
ggplot(aes(x = x_coord, y = y_coord)) +
geom_text(aes(label = value, color = value),
size = 10) +
scale_color_gradient(low = "red", high = "green") +
labs(x = "X Coorindates",
y = "Y Coordinates",
title = "Prior Probabilities of 4x4 Square Region",
color = "Probability") +
theme(axis.text = element_text(size = 11, face = "bold"))
We see that the y-coordiate range of 3 has a high probability of deer activity. In particular, xy = (1, 3) and xy = (2, 3) seem to maximize the chances of seeing a deer.
The likelihood grid
The likelihood in this case describe the probability of seeing a deer in a specific square region given that a deer is actually there. p(Square Region | Deer)
To determine these likelihoods, our deer guide is constantly scouting the areas and making mental notes about what he sees. He documents certain things within each square region that would indicate deer are there. For example, deer droppings, foot prints, actually seeing some deer, and previous successful hunts in a certain region. Using this information he creates a grid of the following likelihoods:
matrix(data = c(0.88, 0.82, 0.88, 0.85, 0.77, 0.65, 0.83, 0.95,
0.98, 0.97, 0.93, 0.94, 0.93, 0.79, 0.68, 0.80),
byrow = TRUE,
nrow = 4, ncol = 4) %>%
as.data.frame() %>%
setNames(c("1", "2", "3", "4")) %>%
pivot_longer(cols = everything(),
names_to = 'x_coord') %>%
mutate(y_coord = rep(1:4, each = 4)) %>%
relocate(y_coord, .before = x_coord) %>%
ggplot(aes(x = x_coord, y = y_coord)) +
geom_text(aes(label = value, color = value),
size = 10) +
scale_color_gradient(low = "red", high = "green") +
labs(x = "X Coorindates",
y = "Y Coordinates",
title = "Likelihoods for each 4x4 Square Region",
subtitle = "p(Region | Seeing Deer)",
color = "Probability") +
theme(axis.text = element_text(size = 11, face = "bold"))
Combining our prior knowledge and likelihoods
To make things easier, I’ll put both the priors and likelihoods into a single data frame.
dat <- data.frame(
coords = c("1,1", "2,1", "3,1", "4,1", "1,2", "2,2", "3,2", "4,2", "1,3", "2,3", "3,3", "4,3", "1,4", "2,4", "3,4", "4,4"),
priors = c(0.01, 0.02, 0.01, 0.1, 0.1, 0.03, 0.03, 0.03,
0.2, 0.2, 0.17, 0.1, 0.01, 0.01, 0.02, 0.01),
likelihoods = c(0.88, 0.82, 0.88, 0.85, 0.77, 0.65, 0.83, 0.95,
0.98, 0.97, 0.93, 0.94, 0.93, 0.79, 0.68, 0.80))
dat
Now he multiplies the prior and likelihood together to summarize his belief of deer in each square region.
dat <- dat %>%
mutate(posterior = round(priors * likelihoods, 2))
dat %>%
ggplot(aes(x = coords, y = posterior)) +
geom_col(color = "black",
fill = "light grey") +
scale_y_continuous(labels = scales::percent_format()) +
theme(axis.text = element_text(size = 11, face = "bold"))
As expected, squares (1,3), (2,3), and (3,3) have the highest probability of observing a deer. Those would be the first areas that our deer hunt guide would want to explore when taking new clients out.
Updating Beliefs After Searching a Region
Since square (1,3) has the highest probability our deer hunt guide decides to take his new clients out there to search for deer. After one day of searching they don’t find any deer. To ensure success tomorrow, he needs to update his knowledge not only about square (1, 3) but about all of the other squares in his 4×4 map.
To update square (1, 3) we use the following equation:
update.posterior = prior * (1 – likelihood) / (1 – prior*likelihood)
coord1_3 <- dat %>% filter(coords == "1,3") coord1_3$priors * (1 - coord1_3$likelihoods) / (1 - coord1_3$priors * coord1_3$likelihoods)
Thew new probability for region (1, 3) is 0.5%. Once we update that square region we can update the other regions using the following equation:
update.prior = prior * (1 / (1 – prior * likelihood))
We can do this for the entire data set all at once:
dat <- dat %>%
mutate(posterior2 = round(priors * (1 / (1 - priors*likelihoods)), 2),
posterior2 = ifelse(coords == "1,3", 0.005, posterior2)) %>%
mutate(updated_posterior = round(posterior2 * likelihoods, 3))
dat %>%
select(coords, posterior, updated_posterior) %>%
pivot_longer(cols = -coords) %>%
ggplot(aes(x = coords, y = value, fill = name)) +
geom_col(position = "dodge") +
scale_y_continuous(labels = scales::percent_format()) +
theme(axis.text = element_text(size = 11, face = "bold"))
matrix(dat$updated_posterior, ncol = 4, nrow = 4, byrow = TRUE) %>%
as.data.frame() %>%
setNames(c("1", "2", "3", "4")) %>%
pivot_longer(cols = everything(),
names_to = 'x_coord') %>%
mutate(y_coord = rep(1:4, each = 4)) %>%
relocate(y_coord, .before = x_coord) %>%
ggplot(aes(x = x_coord, y = y_coord)) +
geom_text(aes(label = value, color = value),
size = 10) +
scale_color_gradient(low = "red", high = "green") +
labs(x = "X Coorindates",
y = "Y Coordinates",
title = "Updated Posterior for each 4x4 Square Region after searching (1,3) and\nnot seeing deer",
color = "Probability") +
theme(axis.text = element_text(size = 11, face = "bold"))
We can see that after updating the posteriors following day 1, hist best approach is to search grid (2, 3) and (3,3) tomorrow, as the updated beliefs indicate that they have a higher probability of having a deer in them.
Conclusion
We can of course continue updating after searching each region until we finally find the deer but we will stop here and allow you to play with the code and continue on if you’d like. This tutorial is just to provide a brief look into how to use Bayesian Search Theory to locate objects in various spaces, so hopefully you can use this method and apply it to other aspects of your life.
The complete code is available on my GitHub page.
A shiny app has always required a server to run. If you wanted to connect data to your users and allow them to interact with it you needed server accessibility. Well, not any more! This week, Ellis Hughes and I explore ShinyLive as an option for creating serverless shiny app. It’s early days, but the future is bright. Watch us walk through trying to learn how to set up a serverless shiny app and figure out the ins and outs of the code.
To watch our screen cast, CLICK HERE.
To access our code, CLICK HERE.