--- title: "The Effects of market conditions on recruitment and completion of clinical trials" author: "Will King" format: html editor: source --- IMPORTANT: Not setup yet # Setup ```{r} library(bayesplot) available_mcmc(pattern = "_nuts_") library(ggplot2) library(patchwork) library(tidyverse) library(rstan) library(tidyr) library(ghibli) library(xtable) #Resources: https://github.com/stan-dev/rstan/wiki/RStan-Getting-Started #save unchanged models instead of recompiling rstan_options(auto_write = TRUE) #allow for multithreaded sampling options(mc.cores = parallel::detectCores()) #test installation, shouldn't get any errors #example(stan_model, package = "rstan", run.dontrun = TRUE) ``` ```{r} ################ Pull data from database ###################### library(RPostgreSQL) driver <- dbDriver("PostgreSQL") get_data <- function(driver) { con <- dbConnect( driver, user='root', password='root', dbname='aact_db', host='will-office' ) on.exit(dbDisconnect(con)) query <- dbSendQuery( con, # "select * from formatted_data_with_planned_enrollment;" " select fdqpe.nct_id --,fdqpe.start_date --,fdqpe.current_enrollment --,fdqpe.enrollment_category ,fdqpe.current_status ,fdqpe.earliest_date_observed ,fdqpe.elapsed_duration ,fdqpe.n_brands as identical_brands ,ntbtu.brand_name_count ,fdqpe.category_id ,fdqpe.final_status ,fdqpe.h_sdi_val --,fdqpe.h_sdi_u95 --,fdqpe.h_sdi_l95 ,fdqpe.hm_sdi_val --,fdqpe.hm_sdi_u95 --,fdqpe.hm_sdi_l95 ,fdqpe.m_sdi_val --,fdqpe.m_sdi_u95 --,fdqpe.m_sdi_l95 ,fdqpe.lm_sdi_val --,fdqpe.lm_sdi_u95 --,fdqpe.lm_sdi_l95 ,fdqpe.l_sdi_val --,fdqpe.l_sdi_u95 --,fdqpe.l_sdi_l95 from formatted_data_with_planned_enrollment fdqpe join \"Formularies\".nct_to_brands_through_uspdc ntbtu on fdqpe.nct_id = ntbtu.nct_id order by fdqpe.nct_id, fdqpe.earliest_date_observed ; " ) df <- fetch(query, n = -1) df <- na.omit(df) query2 <-dbSendQuery(con,"select count(*) from \"DiseaseBurden\".icd10_categories ic where \"level\"=1;") n_categories <- fetch(query2, n = -1) return(list(data=df,ncat=n_categories)) } d <- get_data(driver) df <- d$data n_categories <- d$ncat ################ Format Data ########################### data_formatter <- function(df) { categories <- df["category_id"] x <- df["elapsed_duration"] x["identical_brands"] <- asinh(df$identical_brands) x["brand_name_counts"] <- asinh(df$brand_name_count) x["h_sdi_val"] <- asinh(df$h_sdi_val) x["hm_sdi_val"] <- asinh(df$hm_sdi_val) x["m_sdi_val"] <- asinh(df$m_sdi_val) x["lm_sdi_val"] <- asinh(df$lm_sdi_val) x["l_sdi_val"] <- asinh(df$l_sdi_val) #Setup fixed effects x["status_NYR"] <- ifelse(df["current_status"]=="Not yet recruiting",1,0) x["status_EBI"] <- ifelse(df["current_status"]=="Enrolling by invitation",1,0) x["status_Rec"] <- ifelse(df["current_status"]=="Recruiting",1,0) x["status_ANR"] <- ifelse(df["current_status"]=="Active, not recruiting",1,0) y <- ifelse(df["final_status"]=="Terminated",1,0) #get category list return(list(x=x,y=y)) } train <- data_formatter(df) categories <- df$category_id x <- train$x y <- train$y ``` # Fit Model ```{r} ################################# FIT MODEL ######################################### inherited_cols <- c( "elapsed_duration" #,"identical_brands" #,"brand_name_counts" ,"h_sdi_val" ,"hm_sdi_val" ,"m_sdi_val" ,"lm_sdi_val" ,"l_sdi_val" ,"status_NYR" ,"status_EBI" ,"status_Rec" ,"status_ANR" ) ``` ```{r} beta_list <- list( groups = c( `1`="Infections & Parasites", `2`="Neoplasms", `3`="Blood & Immune system", `4`="Endocrine, Nutritional, and Metabolic", `5`="Mental & Behavioral", `6`="Nervous System", `7`="Eye and Adnexa", `8`="Ear and Mastoid", `9`="Circulatory", `10`="Respiratory", `11`="Digestive", `12`="Skin & Subcutaneaous tissue", `13`="Musculoskeletal", `14`="Genitourinary", `15`="Pregancy, Childbirth, & Puerperium", `16`="Perinatal Period", `17`="Congential", `18`="Symptoms, Signs etc.", `19`="Injury etc.", `20`="External Causes", `21`="Contact with Healthcare", `22`="Special Purposes" ), parameters = c( `1`="Elapsed Duration", # brands `2`="asinh(Generic Brands)", `3`="asinh(Competitors USPDC)", # population `4`="asinh(High SDI)", `5`="asinh(High-Medium SDI)", `6`="asinh(Medium SDI)", `7`="asinh(Low-Medium SDI)", `8`="asinh(Low SDI)", #Status `9`="status_NYR", `10`="status_EBI", `11`="status_Rec", `12`="status_ANR" ) ) get_parameters <- function(stem,class_list) { #get categories and lengths named <- names(class_list) lengths <- sapply(named, (function (x) length(class_list[[x]]))) #describe the grid needed iter_list <- sapply(named, (function (x) 1:lengths[x])) #generate the list of parameters pardf <- generate_parameter_df(stem, iter_list) #add columns with appropriate human-readable names for (name in named) { pardf[paste(name,"_hr",sep="")] <- as.factor( sapply(pardf[name], (function (i) class_list[[name]][i])) ) } return(pardf) } generate_parameter_df <- function(stem, iter_list) { grid <- expand.grid(iter_list) grid["param_name"] <- grid %>% unite(x,colnames(grid),sep=",") grid["param_name"] <- paste(stem,"[",grid$param_name,"]",sep="") return(grid) } group_mcmc_areas <- function( stem,# = "beta" class_list,# = beta_list stanfit,# = fit group_id,# = 2 rename=TRUE, filter=NULL ) { #get all parameter names params <- get_parameters(stem,class_list) #filter down to parameters of interest params <- filter(params,groups == group_id) #Get dataframe with only the rows of interest filtdata <- as.data.frame(stanfit)[params$param_name] #rename columns if (rename) dimnames(filtdata)[[2]] <- params$parameters_hr #get group name for title group_name <- class_list$groups[group_id] #create area plot with appropriate title p <- mcmc_areas(filtdata,prob = 0.8, prob_outer = 0.95) + ggtitle(paste("Parameter distributions for ICD-10 class:",group_name)) + geom_vline(xintercept=0,color="grey",alpha=0.75) d <- pivot_longer(filtdata, everything()) |> group_by(name) |> summarize( mean=mean(value) ,q025 = quantile(value,probs = 0.025) ,q975 = quantile(value,probs = 0.975) ,q05 = quantile(value,probs = 0.05) ,q95 = quantile(value,probs = 0.95) ) return(list(plot=p,quantiles=d,name=group_name)) } parameter_mcmc_areas <- function( stem,# = "beta" class_list,# = beta_list stanfit,# = fit parameter_id,# = 2 rename=TRUE ) { #get all parameter names params <- get_parameters(stem,class_list) #filter down to parameters of interest params <- filter(params,parameters == parameter_id) #Get dataframe with only the rows of interest filtdata <- as.data.frame(stanfit)[params$param_name] #rename columns if (rename) dimnames(filtdata)[[2]] <- params$groups_hr #get group name for title parameter_name <- class_list$parameters[parameter_id] #create area plot with appropriate title p <- mcmc_areas(filtdata,prob = 0.8, prob_outer = 0.95) + ggtitle(parameter_name,"Parameter Distribution") d <- pivot_longer(filtdata, everything()) |> group_by(name) |> summarize( mean=mean(value) ,q025 = quantile(value,probs = 0.025) ,q975 = quantile(value,probs = 0.975) ,q05 = quantile(value,probs = 0.05) ,q95 = quantile(value,probs = 0.95) ) return(list(plot=p,quantiles=d,name=parameter_name)) } ``` ```{r} #generics intervention brand_intervention_ib <- x[c(inherited_cols,"brand_name_counts")] brand_intervention_ib["identical_brands"] <- asinh(sinh(x$identical_brands)+1) #add a single generic brand ``` ```{r} counterfact_marketing_ib <- list( D = ncol(x),# N = nrow(x), L = n_categories$count, y = as.vector(y), ll = as.vector(categories), x = as.matrix(x), mu_mean = 0, mu_stdev = 0.05, sigma_shape = 4, sigma_rate = 20, Nx = nrow(x), llx = as.vector(categories), counterfact_x_tilde = as.matrix(brand_intervention_ib), counterfact_x = as.matrix(x) ) ``` ```{r} fit <- stan( file='Hierarchal_Logistic.stan', data = counterfact_marketing_ib, chains = 4, iter = 5000, seed = 11021585 ) ``` ## Explore data ```{r} ################################# DATA EXPLORATION ############################ driver <- dbDriver("PostgreSQL") con <- dbConnect( driver, user='root', password='root', dbname='aact_db', host='will-office' ) #Plot histogram of count of snapshots df3 <- dbGetQuery( con, "select nct_id,final_status,count(*) from formatted_data_with_planned_enrollment fdwpe group by nct_id,final_status ;" ) #df3 <- fetch(query3, n = -1) ggplot(data=df3, aes(x=count, fill=final_status)) + geom_histogram(binwidth=1) + ggtitle("Histogram of snapshots per trial (matched trials)") + xlab("Snapshots per trial") ggsave("./Images/HistSnapshots.png") #Plot duration for terminated vs completed df4 <- dbGetQuery( con, " select nct_id, start_date , primary_completion_date, overall_status , primary_completion_date - start_date as duration from ctgov.studies s where nct_id in (select distinct nct_id from http.download_status ds) ;" ) #df4 <- fetch(query4, n = -1) ggplot(data=df4, aes(x=duration,fill=overall_status)) + geom_histogram()+ ggtitle("Histogram of trial durations") + xlab("duration")+ facet_wrap(~overall_status) ggsave("./Images/HistTrialDurations_Faceted.png") df5 <- dbGetQuery( con, " with cte1 as ( select nct_id, start_date , primary_completion_date, overall_status , primary_completion_date - start_date as duration from ctgov.studies s where nct_id in (select distinct nct_id from http.download_status ds) ), cte2 as ( select nct_id,count(*) as snapshot_count from formatted_data_with_planned_enrollment fdwpe group by nct_id ) select a.nct_id, a.overall_status, a.duration,b.snapshot_count from cte1 as a join cte2 as b on a.nct_id=b.nct_id ;" ) df5$overall_status <- as.factor(df5$overall_status) ggplot(data=df5, aes(x=duration,y=snapshot_count,color=overall_status)) + geom_jitter() + ggtitle("Comparison of duration, status, and snapshot_count") + xlab("duration") + ylab("snapshot count") ggsave("./Images/SnapshotsVsDurationVsTermination.png") dbDisconnect(con) #get number of trials and snapshots in each category group_trials_by_category <- as.data.frame(aggregate(category_id ~ nct_id, df, max)) group_trials_by_category <- as.data.frame(group_trials_by_category) ggplot(data = group_trials_by_category, aes(x=category_id)) + geom_bar(binwidth=1,color="black",fill="seagreen") + scale_x_continuous(breaks=scales::pretty_breaks(n=22)) + labs( title="bar chart of trial categories" ,x="Category ID" ,y="Count" ) ggsave("./Images/CategoryCounts.png") summary(df5) ``` ```{r} category_count <- group_trials_by_category |> group_by(category_id) |> count() ``` ## Fit Results ```{r} ################################# ANALYZE ##################################### print(fit) ``` ### Investigating parameter distributions ```{r} #g1 <- group_mcmc_areas("beta",beta_list,fit,1) gx <- c() #grab parameters for every category with more than 8 observations for (i in category_count$category_id[category_count$n >= 8]) { print(i) #Print parameter distributions gi <- group_mcmc_areas("beta",beta_list,fit,i) #add way to filter groups ggsave( paste0("./Images/DirectEffects/Parameters/group_",i,"_",gi$name,".png") ,plot=gi$plot ) gx <- c(gx,gi) #Get Quantiles and means for parameters table <- xtable(gi$quantiles, floating=FALSE ,latex.environments = NULL ,booktabs = TRUE ,zap=getOption("digits") ) write_lines(table,paste0("./latex_output/DirectEffects/group_",gi$name,".tex")) } ``` ```{r} px <- c() for (i in c(1,2,3,9,10,11,12)) { #Print parameter distributions pi <- parameter_mcmc_areas("beta",beta_list,fit,i) #add way to filter groups ggsave( paste0("./Images/DirectEffects/Parameters/parameters_",i,"_",pi$name,".png") ,plot=pi$plot ) px <- c(px,pi) #Get Quantiles and means for parameters table <- xtable(pi$quantiles, floating=FALSE ,latex.environments = NULL ,booktabs = TRUE ,zap=getOption("digits") ) write_lines(table,paste0("./latex_output/DirectEffects/parameters_",i,"_",pi$name,".tex")) } ``` Note these have 95% outer CI and 80% inner (shaded) 1) "Elapsed Duration", 2) "asinh(Generic Brands)", 3) "asinh(Competitors USPDC)", 4) "asinh(High SDI)", 5) "asinh(High-Medium SDI)", 6) "asinh(Medium SDI)", 7) "asinh(Low-Medium SDI)", 8) "asinh(Low SDI)", 9) "status_NYR", 10) "status_EBI", 11) "status_Rec", 12) "status_ANR", ```{r} print(px[4]$plot + px[7]$plot) ggsave("./Images/DirectEffects/Parameters/2+3_generic_and_uspdc.png") ``` # Counterfactuals ```{r} generated_ib <- gqs( fit@stanmodel, data=counterfact_marketing_ib, draws=as.matrix(fit), seed=11021585 ) ``` ```{r} df_ib_p <- data.frame( p_prior=as.vector(extract(generated_ib, pars="p_prior")$p_prior) ,p_predicted = as.vector(extract(generated_ib, pars="p_predicted")$p_predicted) ) df_ib_prior <- data.frame( mu_prior = as.vector(extract(generated_ib, pars="mu_prior")$mu_prior) ,sigma_prior = as.vector(extract(generated_ib, pars="sigma_prior")$sigma_prior) ) #p_prior ggplot(df_ib_p, aes(x=p_prior)) + geom_density() + labs( title="Implied Prior Distribution P" ,subtitle="" ,x="Probability Domain 'p'" ,y="Probability Density" ) ggsave("./Images/DirectEffects/prior_p.png") #p_posterior ggplot(df_ib_p, aes(x=p_predicted)) + geom_density() + labs( title="Implied Posterior Distribution P" ,subtitle="" ,x="Probability Domain 'p'" ,y="Probability Density" ) ggsave("./Images/DirectEffects/posterior_p.png") #mu_prior ggplot(df_ib_prior) + geom_density(aes(x=mu_prior)) + labs( title="Prior - Mu" ,subtitle="same prior for all Mu values" ,x="Mu" ,y="Probability" ) ggsave("./Images/DirectEffects/prior_mu.png") #sigma_posterior ggplot(df_ib_prior) + geom_density(aes(x=sigma_prior)) + labs( title="Prior - Sigma" ,subtitle="same prior for all Sigma values" ,x="Sigma" ,y="Probability" ) ggsave("./Images/DirectEffects/prior_sigma.png") ``` ```{r} check_hmc_diagnostics(fit) ``` ### Intervention: Alternatives #### Generic Alternative ```{r} counterfact_predicted_ib <- data.frame( p_predicted_default = as.vector(extract(generated_ib, pars="p_predicted_default")$p_predicted_default) ,p_predicted_intervention = as.vector(extract(generated_ib, pars="p_predicted_intervention")$p_predicted_intervention) ,predicted_difference = as.vector(extract(generated_ib, pars="predicted_difference")$predicted_difference) ) ggplot(counterfact_predicted_ib, aes(x=p_predicted_default)) + geom_density() + labs( title="Predicted Distribution of 'p'" ,subtitle="Intervention: None" ,x="Probability Domain 'p'" ,y="Probability Density" ) ggsave("./Images/DirectEffects/default_p_generic_intervention_base.png") ggplot(counterfact_predicted_ib, aes(x=p_predicted_intervention)) + geom_density() + labs( title="Predicted Distribution of 'p'" ,subtitle="Intervention: Add a single generic competitor" ,x="Probability Domain 'p'" ,y="Probability Density" ) ggsave("./Images/DirectEffects/default_p_generic_intervention_interv.png") ggplot(counterfact_predicted_ib, aes(x=predicted_difference)) + geom_density() + labs( title="Predicted Distribution of differences 'p'" ,subtitle="Intervention: Add a single generic competitor" ,x="Difference in 'p' under treatment" ,y="Probability Density" ) ggsave("./Images/DirectEffects/default_p_generic_intervention_distdiff.png") ``` ```{r} pddf_ib <- data.frame(extract(generated_ib, pars="predicted_difference")$predicted_difference) |> pivot_longer(X1:X1343) #TODO: Fix Category names pddf_ib["entry_idx"] <- as.numeric(gsub("\\D","",pddf_ib$name)) pddf_ib["category"] <- sapply(pddf_ib$entry_idx, function(i) df$category_id[i]) pddf_ib["category_name"] <- sapply(pddf_ib$category, function(i) beta_list$groups[i]) ggplot(pddf_ib, aes(x=value,)) + geom_density(bins=100) + labs( title = "Distribution of predicted differences" ,subtitle = "Intervention: add a single generic competitor" ,x = "Difference in probability due to intervention" ,y = "Probability Density" ) + geom_vline(aes(xintercept = 0), color = "skyblue", linetype="dashed") ggsave("./Images/DirectEffects/p_generic_intervention_distdiff_styled.png") ggplot(pddf_ib, aes(x=value,)) + geom_density(bins=100) + facet_wrap( ~factor( category_name, levels=beta_list$groups ) , labeller = label_wrap_gen(multi_line = TRUE) , ncol=5) + labs( title = "Distribution of predicted differences | By Group" ,subtitle = "Intervention: add a single generic competitor" ,x = "Difference in probability due to intervention" ,y = "Probability Density" ) + geom_vline(aes(xintercept = 0), color = "skyblue", linetype="dashed") + theme(strip.text.x = element_text(size = 8)) ggsave("./Images/DirectEffects/p_generic_intervention_distdiff_by_group.png") ggplot(pddf_ib, aes(x=value,)) + geom_histogram(bins=100) + facet_wrap( ~factor( category_name, levels=beta_list$groups ) , labeller = label_wrap_gen(multi_line = TRUE) , ncol=5) + labs( title = "Histogram of predicted differences | By Group" ,subtitle = "Intervention: add a single generic competitor" ,x = "Difference in probability due to intervention" ,y = "Predicted counts" ) + #xlim(-0.25,0.1) + geom_vline(aes(xintercept = 0), color = "skyblue", linetype="dashed") + theme(strip.text.x = element_text(size = 8)) ggsave("./Images/DirectEffects/p_generic_intervention_histdiff_by_group.png") ``` Get the probability of increase over probability of a decrease ```{r} mean(counterfact_predicted_ib$predicted_difference) ``` Thus adding a single generic competitor increases the probability of termination by 16.55% on average for the snapshots investigated. ```{r} n = length(counterfact_predicted_ib$p_predicted_intervention) mean(rbinom(n,1,as.vector(counterfact_predicted_ib$p_predicted_intervention))) mean(rbinom(n,1,as.vector(counterfact_predicted_ib$p_predicted_default))) ``` #### USP DC Alternative ```{r} #formulary intervention brand_intervention_bnc <- x[c(inherited_cols,"identical_brands")] brand_intervention_bnc["brand_name_counts"] <- asinh(sinh(x$brand_name_counts)+1) #add a single formulary competitor brand ``` ```{r} counterfact_marketing_bnc <- list( D = ncol(x),# N = nrow(x), L = n_categories$count, y = as.vector(y), ll = as.vector(categories), x = as.matrix(x), mu_mean = 0, mu_stdev = 0.05, sigma_shape = 4, sigma_rate = 20, Nx = nrow(x), llx = as.vector(categories), counterfact_x_tilde = as.matrix(brand_intervention_bnc), counterfact_x = as.matrix(x) ) ``` ```{r} generated_bnc <- gqs( fit@stanmodel, data=counterfact_marketing_bnc, draws=as.matrix(fit), seed=11021585 ) ``` ```{r} counterfact_predicted_bnc <- data.frame( p_predicted_default = as.vector(extract(generated_bnc, pars="p_predicted_default")$p_predicted_default) ,p_predicted_intervention = as.vector(extract(generated_bnc, pars="p_predicted_intervention")$p_predicted_intervention) ,predicted_difference = as.vector(extract(generated_bnc, pars="predicted_difference")$predicted_difference) ) ggplot(counterfact_predicted_bnc, aes(x=p_predicted_default)) + geom_density() + labs( title="Predicted Distribution of 'p'" ,subtitle="Intervention: None" ,x="Probability Domain 'p'" ,y="Probability Density" ) ggsave("./Images/DirectEffects/default_p_uspdc_intervention_base.png") ggplot(counterfact_predicted_bnc, aes(x=p_predicted_intervention)) + geom_density() + labs( title="Predicted Distribution of 'p'" ,subtitle="Intervention: Add a single USP DC competitor" ,x="Probability Domain 'p'" ,y="Probability Density" ) ggsave("./Images/DirectEffects/default_p_uspdc_intervention_interv.png") ggplot(counterfact_predicted_bnc, aes(x=predicted_difference)) + geom_density() + labs( title="Predicted Distribution of differences 'p'" ,subtitle="Intervention: Add a single USP DC competitor" ,x="Difference in 'p' under treatment" ,y="Probability Density" ) ggsave("./Images/DirectEffects/default_p_uspdc_intervention_distdiff.png") ``` ```{r} pddf_bnc <- data.frame(extract(generated_bnc, pars="predicted_difference")$predicted_difference) |> pivot_longer(X1:X1343) #Add Category names pddf_bnc["entry_idx"] <- as.numeric(gsub("\\D","",pddf_bnc$name)) pddf_bnc["category"] <- sapply(pddf_bnc$entry_idx, function(i) df$category_id[i]) pddf_bnc["category_name"] <- sapply(pddf_bnc$category, function(i) beta_list$groups[i]) ggplot(pddf_bnc, aes(x=value,)) + geom_density(bins=100) + labs( title = "Distribution of predicted differences" ,subtitle = "Intervention: add a single USP DC competitor" ,x = "Difference in probability due to intervention" ,y = "Probability Density" ) + geom_vline(aes(xintercept = 0), color = "skyblue", linetype="dashed") ggsave("./Images/DirectEffects/p_uspdc_intervention_distdiff_styled.png") ggplot(pddf_bnc, aes(x=value,)) + geom_density(bins=100) + facet_wrap( ~factor( category_name, levels=beta_list$groups ) , labeller = label_wrap_gen(multi_line = TRUE) , ncol=5) + labs( title = "Distribution of predicted differences in 'p' | By Group" ,subtitle = "Intervention: add a single USP DC competitor" ,x = "Difference in probability due to intervention" ,y = "Probability Density" ) + geom_vline(aes(xintercept = 0), color = "skyblue", linetype="dashed") + theme(strip.text.x = element_text(size = 8)) ggsave("./Images/DirectEffects/p_uspdc_intervention_distdiff_by_group.png") ggplot(pddf_bnc, aes(x=value,)) + geom_histogram(bins=100) + facet_wrap( ~factor( category_name, levels=beta_list$groups ) , labeller = label_wrap_gen(multi_line = TRUE) , ncol=5) + labs( title = "Histogram of predicted differences in 'p' | By Group" ,subtitle = "Intervention: add a single USP DC competitor" ,x = "Difference in probability due to intervention" ,y = "Predicted counts" ) + #xlim(-0.25,0.1) + geom_vline(aes(xintercept = 0), color = "skyblue", linetype="dashed") + theme(strip.text.x = element_text(size = 8)) ggsave("./Images/DirectEffects/p_uspdc_intervention_histdiff_by_group.png") ``` TODO: add density plot of (x,y,z) (date,value,counts) - with and without faceting ```{r} mean(counterfact_predicted_bnc$predicted_difference) ``` Addin a single USP DC competitor increases/reduces the probability of completion by 16.47% on average for the snapshots of trials that we have. ### Intervention: Marginal increase in time to finish enrollment ```{r} #| eval: false pddf <- data.frame(extract(generated, pars="predicted_difference")$predicted_difference) |> pivot_longer(X1:X189) pddf["entry_idx"] <- as.numeric(gsub("\\D","",pddf$name)) pddf["category"] <- sapply(pddf$entry_idx, function(i) counterfact_categories[i]) pddf["category_name"] <- sapply(pddf$category, function(i) beta_list$groups[i]) ggplot(pddf, aes(x=value,)) + geom_histogram(bins=100) + labs( title = "Distribution of predicted differences" ,x = "Difference in probability due to intervention" ,y = "Predicted counts" ) + xlim(-0.3,0.1) + geom_vline(aes(xintercept = 0), color = "skyblue", linetype="dashed") ggplot(pddf, aes(x=value,)) + geom_histogram(bins=100) + facet_wrap( ~factor( category_name, levels=beta_list$groups ) , labeller = label_wrap_gen(multi_line = TRUE) , ncol=5) + labs( title = "Distribution of predicted differences", subtitle = "By group" ,x = "Difference in probability due to intervention" ,y = "Predicted counts" ) + xlim(-0.25,0.1) + geom_vline(aes(xintercept = 0), color = "skyblue", linetype="dashed") + theme(strip.text.x = element_text(size = 8)) ``` Recall that we had really tight zero priors. # Diagnostics ```{r} #| eval: false #trace plots plot(fit, pars=c("mu"), plotfun="trace") for (i in 1:4) { print( mcmc_rank_overlay( fit, pars=c( paste0("mu[",4*i-3,"]"), paste0("mu[",4*i-2,"]"), paste0("mu[",4*i-1,"]"), paste0("mu[",4*i,"]") ), n_bins=100 )+ legend_move("top") + scale_colour_ghibli_d("KikiMedium") ) } ``` ```{r} #| eval: false plot(fit, pars=c("sigma"), plotfun="trace") for (i in 1:4) { print( mcmc_rank_overlay( fit, pars=c( paste0("sigma[",4*i-3,"]"), paste0("sigma[",4*i-2,"]"), paste0("sigma[",4*i-1,"]"), paste0("sigma[",4*i,"]") ), n_bins=100 )+ legend_move("top") + scale_colour_ghibli_d("KikiMedium") ) } ``` ```{r} #| eval: false #other diagnostics logpost <- log_posterior(fit) nuts_prmts <- nuts_params(fit) posterior <- as.array(fit) ``` ```{r} #| eval: false color_scheme_set("darkgray") div_style <- parcoord_style_np(div_color = "green", div_size = 0.05, div_alpha = 0.4) mcmc_parcoord(posterior, regex_pars = "mu", np=nuts_prmts, np_style = div_style, alpha = 0.05) ``` ```{r} #| eval: false for (i in 1:4) { mus = sapply(3:0, function(j) paste0("mu[",4*i-j ,"]")) print( mcmc_pairs( posterior, np = nuts_prmts, pars=c( mus, "lp__" ), off_diag_args = list(size = 0.75) ) ) } ``` ```{r} #| eval: false mcmc_parcoord(posterior,regex_pars = "sigma", np=nuts_prmts, alpha=0.05) ``` ```{r} #| eval: false for (i in 1:4) { params = sapply(3:0, function(j) paste0("sigma[",4*i-j ,"]")) print( mcmc_pairs( posterior, np = nuts_prmts, pars=c( params, "lp__" ), off_diag_args = list(size = 0.75) ) ) } ``` ```{r} #| eval: false for (k in 1:22) { for (i in 1:4) { params = sapply(3:0, function(j) paste0("beta[",k,",",4*i-j ,"]")) print( mcmc_pairs( posterior, np = nuts_prmts, pars=c( params, "lp__" ), off_diag_args = list(size = 0.75) ) ) }} ``` # TODO - [ ] Double check data flow. (Write summary of this in human readable form) - Is it the data we want from the database - Training - Counterfactual Evaluation - choose a single snapshot per trial. - Is the model in STAN well specified. - [ ] work on LOO validation of model