Datasets:

chuxuan
/

REPRO-Bench

	########################################################
	##### ESLR - RD + MATCHING PLOTING - AgCensus Data #####
	########################################################

	rm(list = ls()) # Clear variables

	require(foreign)
	require(ggplot2)
	require(rgdal)
	require(rgeos)
	require(RColorBrewer) # creates nice color schemes
	require(maptools) # loads sp library too
	require(scales) # customize scales
	require(gridExtra) # mutiple plots
	require(plyr) # join function
	require(dplyr)
	require(mapproj) # projection tools
	require(raster) # raster tools
	require(ggvis) # visualize estimators
	require(rdrobust) # rd estimation tools
	require(stringdist) # approximate string matching
	require(gdata)
	require(rdd) # sorting tests
	require(stargazer) # format tables
	require(haven)
	require(readstata13)
	require(TOSTER)
	require(MatchIt)
	require(imputeTS)
	require(opmatch)
	require(cem)
	require(tcltk)
	require(extrafont)

	########################################

	## Load IV Censo Agropecuario Data:
	censo_ag_wreform <- read.dta13(file="Data/censo_ag_wreform.dta")

	########################################

	## Making Standarized Coefficient Plots:

	# Set aesthetics:
	aesthetics <- list(
	theme_bw(),
	theme(legend.title=element_blank(),
	text=element_text(family="Palatino"),
	#legend.justification=c(0,0),
	#legend.position= "right", #c(1,0),
	#panel.grid.minor=element_blank(),
	#panel.grid.major=element_blank(),
	plot.background=element_rect(colour="white",fill="white"),
	panel.grid.major=element_blank(),
	panel.grid.minor=element_blank(),
	axis.text.x=element_text(angle=45, face="bold",hjust=1),
	axis.title.y=element_text(face="bold.italic"),
	axis.title.x=element_blank())) #(face="bold.italic")))

	########################################


	lm.beta <- function (MOD, dta,y="ln_agprod")
	{
	b <- MOD$coef[1]
	model.dta <- filter(dta, norm_dist > -1*MOD$bws["h","left"] & norm_dist < MOD$bws["h","right"] )
	sx <- sd(model.dta[,c("Above500")])
	#sx <- sd(model.dta[,c("norm_dist")])
	sy <- sd((model.dta[,c(y)]),na.rm=TRUE)
	beta <- b * sx/sy
	return(beta)
	}
	lm.beta.ses <- function (MOD, dta,y="ln_agprod")
	{
	b <- MOD$se[1]
	model.dta <- filter(dta, norm_dist > -1*MOD$bws["h","left"] & norm_dist < MOD$bws["h","right"] )
	sx <- sd(model.dta[,c("Above500")])
	#sx <- sd(model.dta[,c("norm_dist")])
	sy <- sd((model.dta[,c(y)]),na.rm=TRUE)
	beta <- b * sx/sy
	return(beta)
	}

	lm.beta.match <- function (MOD, dta,y="ln_agprod")
	{
	b <- MOD[2,1]
	model.dta <- dta # filter(dta, norm_dist > -1*MOD$bws["h","left"] & norm_dist < MOD$bws["h","right"] )
	sx <- sd(model.dta[,c("reform")],na.rm = TRUE)
	#sx <- sd(model.dta[,c("norm_dist")])
	sy <- sd((model.dta[,c(y)]),na.rm=TRUE)
	beta <- b * sx/sy
	return(beta)
	}
	lm.beta.ses.match <- function (MOD, dta,y="ln_agprod")
	{
	b <- MOD[2,2]
	model.dta <- dta # filter(dta, norm_dist > -1*MOD$bws["h","left"] & norm_dist < MOD$bws["h","right"] )
	sx <- sd(model.dta[,c("reform")],na.rm = TRUE)
	#sx <- sd(model.dta[,c("norm_dist")])
	sy <- sd((model.dta[,c(y)]),na.rm=TRUE)
	beta <- b * sx/sy
	return(beta)
	}

	winsor <- function (x, fraction=.01)
	{
	if(length(fraction) != 1 \|\| fraction < 0 \|\|
	fraction > 0.5) {
	stop("bad value for 'fraction'")
	}
	lim <- quantile(x, probs=c(fraction, 1-fraction),na.rm = TRUE)
	x[ x < lim[1] ] <- NA #lim[1] 8888
	x[ x > lim[2] ] <- NA #lim[2] 8888
	x
	}

	winsor1 <- function (x, fraction=.01)
	{
	if(length(fraction) != 1 \|\| fraction < 0 \|\|
	fraction > 0.5) {
	stop("bad value for 'fraction'")
	}
	lim <- quantile(x, probs=c(fraction, 1-fraction),na.rm = TRUE)
	x[ x < lim[1] ] <- lim[1] #lim[1] 8888
	x[ x > lim[2] ] <- lim[2] #lim[2] 8888
	x
	}

	winsor2 <-function (x, multiple=3)
	{
	if(length(multiple) != 1 \|\| multiple <= 0) {
	stop("bad value for 'multiple'")
	}
	med <- median(x)
	y <- x - med
	sc <- mad(y, center=0) * multiple
	y[ y > sc ] <- sc
	y[ y < -sc ] <- -sc
	y + med
	}


	########################################

	polys <- c(1) # 1
	kernels <- c("triangular")
	bwsel <- c("mserd")
	num_outcomes <- 3 # 3 ag prod; staple share + 2 yields; cash + 2 yields; income results
	matching_methods <- c("nearest", "full", "cem", "optimal")
	num_ests <- (length(polys)(length(kernels)length(bwsel)) + length(matching_methods))*num_outcomes
	estimates <-data.frame(y_var = rep(0, num_ests),
	estimate = rep(0, num_ests),
	ses = rep(0, num_ests),
	p = rep(0,num_ests), ks = rep(0,num_ests), bs = rep(0,num_ests),
	nsl= rep(0,num_ests), nsr= rep(0,num_ests), nslII= rep(0,num_ests),
	nsrII= rep(0,num_ests), nslIII= rep(0,num_ests), nsrIII= rep(0,num_ests),
	est_method = rep(0,num_ests))
	censo_ag_wreform_tev <- mutate(censo_ag_wreform, ln_agprodII = ln_agprod, ln_agprod = ln_agprod_pricew_crops)

	## Other covariates for matching:
	ag.grouped <- group_by(censo_ag_wreform_tev,Expropretario_ISTA)
	ag.grouped <- mutate(ag.grouped, num_per_owner = n())
	censo_ag_wreform_tev$num_per_owner<- ag.grouped$num_per_owner
	censo_ag_wreform_tev$mult_per_owner <- ifelse(censo_ag_wreform_tev$num_per_owner > 1, 1, 0)

	# Het by Distance to Urban Centers:
	canton_covs <- read_dta("Data/cantons_dists.dta")
	canton_covs <- canton_covs %>%
	mutate(CODIGO = (as_factor(COD_CTON)))

	canton_covs <- canton_covs %>%
	mutate(CODIGO = gsub("(?<![0-9])0+", "", CODIGO, perl = TRUE)) %>%
	mutate(CODIGO = as.numeric(CODIGO)) %>%
	dplyr::select(CODIGO,dist_ES_capital, dist_dept_capitals)

	censo_ag_wreform_tev <- left_join(censo_ag_wreform_tev,canton_covs, by="CODIGO")

	censo_ag_wreform_tev <- censo_ag_wreform_tev %>%
	mutate(Close_ES_Capital = ifelse(dist_ES_capital < 50000,1,0),
	Close_Dept_Capitals = ifelse(dist_dept_capitals < 50000,1,0),
	canton_land_suit = ifelse(is.na(canton_land_suit),0,canton_land_suit))

	censo_ag_wreform_tev2 <- censo_ag_wreform_tev
	years <- 2007
	for (i in years) {

	# Estimate and Save RD for configurations:

	# Agricultural Variables -- RD Estimates:
	count <-1
	for (p in polys) {
	for (k in kernels) {
	for (b in bwsel) {


	# Cash Crop Share:
	rdests <- rdrobust(y = winsor(censo_ag_wreform_tev$CashCrop_Share),
	x=(censo_ag_wreform_tev$norm_dist),
	c = 0,
	p = p,
	q = p +1,
	kernel = k,
	bwselect = b,
	cluster=(censo_ag_wreform_tev$Expropretario_ISTA), vce="hc1")
	estimates[count,c("estimate")] <-lm.beta(MOD=rdests, dta=censo_ag_wreform_tev, y="CashCrop_Share")
	estimates[count,c("ses")] <- lm.beta.ses(MOD=rdests, dta=censo_ag_wreform_tev, y="CashCrop_Share")

	estimates[count,c("y_var")] <- "Cash Crop Share"
	estimates[count,c("est_method")] <- paste0("RD: Local ", ifelse(p==1,"Linear","Quadratic"), " Polynomial")
	count <- count + 1

	# Sugar Cane Yield:
	rdests <- rdrobust(y = (censo_ag_wreform_tev$SugarCane_Yield),
	x=(censo_ag_wreform_tev$norm_dist),
	c = 0,
	p = p,
	q = p +1,
	kernel = k,
	#bwselect = b,
	h = 102.877,
	b = 166.088,
	cluster=(censo_ag_wreform_tev$Expropretario_ISTA), vce="hc1")
	estimates[count,c("estimate")] <-lm.beta(MOD=rdests, dta=censo_ag_wreform_tev, y="SugarCane_Yield")
	estimates[count,c("ses")] <- lm.beta.ses(MOD=rdests, dta=censo_ag_wreform_tev, y="SugarCane_Yield") #/2

	estimates[count,c("y_var")] <- "Sugar Cane Yield"
	estimates[count,c("est_method")] <- paste0("RD: Local ", ifelse(p==1,"Linear","Quadratic"), " Polynomial")
	count <- count + 1

	# Coffee Yield:
	rdests <- rdrobust(y = (censo_ag_wreform_tev$Coffee_Yield),
	x=(censo_ag_wreform_tev$norm_dist),
	c = 0,
	p = p,
	q = p +1,
	kernel = k,
	bwselect = b,
	cluster=(censo_ag_wreform_tev$Expropretario_ISTA), vce="hc1")
	estimates[count,c("estimate")] <-lm.beta(MOD=rdests, dta=censo_ag_wreform_tev, y="Coffee_Yield")
	estimates[count,c("ses")] <- lm.beta.ses(MOD=rdests, dta=censo_ag_wreform_tev, y="Coffee_Yield")

	estimates[count,c("y_var")] <- "Coffee Yield"
	estimates[count,c("est_method")] <- paste0("RD: Local ", ifelse(p==1,"Linear","Quadratic"), " Polynomial")
	count <- count + 1

	# Staple Crop Share:
	rdests <- rdrobust(y = (censo_ag_wreform_tev$StapleCrop_Share),
	x=(censo_ag_wreform_tev$norm_dist),
	c = 0,
	p = p,
	q = p +1,
	kernel = k,
	bwselect = b,
	cluster=(censo_ag_wreform_tev$Expropretario_ISTA), vce="hc1")
	estimates[count,c("estimate")] <-lm.beta(MOD=rdests, dta=censo_ag_wreform_tev, y="StapleCrop_Share")
	estimates[count,c("ses")] <- lm.beta.ses(MOD=rdests, dta=censo_ag_wreform_tev, y="StapleCrop_Share")

	estimates[count,c("y_var")] <- "Staple Crop Share"
	estimates[count,c("est_method")] <- paste0("RD: Local ", ifelse(p==1,"Linear","Quadratic"), " Polynomial")
	count <- count + 1

	# Bean Yield:
	rdests <- rdrobust(y =censo_ag_wreform_tev$Beans_Yield, # winsor1(censo_ag_wreform_tev$Beans_Yield,fraction = 0.025)
	x=(censo_ag_wreform_tev$norm_dist),
	c = 0,
	p = p,
	q = p +1,
	kernel = k,
	# bwselect = b,
	h = 122.64,
	b = 207.42,
	cluster=(censo_ag_wreform_tev$Expropretario_ISTA), vce="hc1")
	estimates[count,c("estimate")] <-lm.beta(MOD=rdests, dta=censo_ag_wreform_tev, y="Beans_Yield")
	estimates[count,c("ses")] <- lm.beta.ses(MOD=rdests, dta=censo_ag_wreform_tev, y="Beans_Yield")

	estimates[count,c("y_var")] <- "Beans Yield"
	estimates[count,c("est_method")] <- paste0("RD: Local ", ifelse(p==1,"Linear","Quadratic"), " Polynomial")
	count <- count + 1

	# Maize Yield:
	rdests <- rdrobust(y = (censo_ag_wreform_tev$Maize_Yield),
	x=(censo_ag_wreform_tev$norm_dist),
	c = 0,
	p = p,
	q = p +1,
	kernel = k,
	#bwselect = b,
	h = 91.611 ,
	b = 146.499 ,
	cluster=(censo_ag_wreform_tev$Expropretario_ISTA), vce="hc1")
	estimates[count,c("estimate")] <-lm.beta(MOD=rdests, dta=censo_ag_wreform_tev, y="Maize_Yield")
	estimates[count,c("ses")] <- lm.beta.ses(MOD=rdests, dta=censo_ag_wreform_tev, y="Maize_Yield")

	estimates[count,c("y_var")] <- "Maize Yield"
	estimates[count,c("est_method")] <- paste0("RD: Local ", ifelse(p==1,"Linear","Quadratic"), " Polynomial")
	count <- count + 1

	# Revenues:
	rdests <- rdrobust(y = (censo_ag_wreform_tev$ln_agprod),
	x=(censo_ag_wreform_tev$norm_dist),
	c = 0,
	p = p,
	q = p +1,
	kernel = k,
	bwselect = b,
	cluster=(censo_ag_wreform_tev$Expropretario_ISTA), vce="hc1")
	estimates[count,c("estimate")] <-lm.beta(MOD=rdests, dta=censo_ag_wreform_tev, y="ln_agprod")
	estimates[count,c("ses")] <- lm.beta.ses(MOD=rdests, dta=censo_ag_wreform_tev, y="ln_agprod")

	estimates[count,c("y_var")] <- "Revenues per ha"
	estimates[count,c("est_method")] <- paste0("RD: Local ", ifelse(p==1,"Linear","Quadratic"), " Polynomial")
	count <- count + 1

	# Profits:
	rdests <- rdrobust(y = (censo_ag_wreform_tev$ln_agprodII),
	x=censo_ag_wreform_tev$norm_dist,
	c = 0,
	p = p,
	q = p +1,
	kernel = k,
	bwselect = b,
	cluster=(censo_ag_wreform_tev$Expropretario_ISTA), vce="hc1")
	estimates[count,c("estimate")] <-lm.beta(MOD=rdests, dta=censo_ag_wreform_tev, y="ln_agprodII")
	estimates[count,c("ses")] <- lm.beta.ses(MOD=rdests, dta=censo_ag_wreform_tev, y="ln_agprodII")

	estimates[count,c("y_var")] <- "Profits per ha"
	estimates[count,c("est_method")] <- paste0("RD: Local ", ifelse(p==1,"Linear","Quadratic"), " Polynomial")
	count <- count + 1

	# TFP:
	rdests <- rdrobust(y = (censo_ag_wreform_tev$ln_tfp_geo),
	x=censo_ag_wreform_tev$norm_dist,
	c = 0,
	p = p,
	q = p +1,
	kernel = k,
	bwselect = b,
	cluster=(censo_ag_wreform_tev$Expropretario_ISTA), vce="hc1")
	estimates[count,c("estimate")] <-lm.beta(MOD=rdests, dta=censo_ag_wreform_tev, y="ln_tfp_geo")
	estimates[count,c("ses")] <- lm.beta.ses(MOD=rdests, dta=censo_ag_wreform_tev, y="ln_tfp_geo")

	estimates[count,c("y_var")] <- "Farm Productivity"
	estimates[count,c("est_method")] <- paste0("RD: Local ", ifelse(p==1,"Linear","Quadratic"), " Polynomial")
	count <- count + 1
	}
	}
	}

	# Agricultural Variables -- Matching Estimates:
	for (m in matching_methods) {

	## Match Datasets:
	to_match <- filter(censo_ag_wreform_tev, !is.na(reform))
	covs <- c("canton_mean_rain","canton_land_suit", "canton_elev_dem_30sec",
	"canton_coffee_suit","sugarcane_suit","miaze_suit","bean_suit","canton_mean_rain",
	"mult_per_owner",
	"dist_ES_capital" , "dist_dept_capitals",
	"Area_has")
	to_match<-to_match[complete.cases(to_match[,covs]),]
	matched.data<-
	matchit(reform ~ canton_coffee_suit + sugarcane_suit + miaze_suit +
	bean_suit + canton_mean_rain + canton_land_suit + canton_elev_dem_30sec +
	mult_per_owner +
	dist_ES_capital + dist_dept_capitals +
	Area_has, data = to_match,
	method = m)

	# Matching estimate

	# Cash Crop Share
	fit1 <- lm(CashCrop_Share ~ reform, data = match.data(matched.data), weights = weights)
	ests<- coeftest(fit1, vcov. = vcovCL, cluster = ~subclass)

	estimates[count,c("estimate")] <-lm.beta.match(MOD=ests, dta=censo_ag_wreform_tev, y="CashCrop_Share")
	estimates[count,c("ses")] <- lm.beta.ses.match(MOD=ests, dta=censo_ag_wreform_tev, y="CashCrop_Share")

	estimates[count,c("y_var")] <- "Cash Crop Share"
	estimates[count,c("est_method")] <- paste0("Matching: ",
	case_when(m=="optimal" ~ "Optimal",
	m=="nearest" ~ "Nearest Neighbor",
	m=="full" ~ "Full",
	m=="cem" ~ "Coarse Exact"),
	" Matching")
	count <- count + 1

	# Sugar Cane
	fit1 <- lm(SugarCane_Yield ~ reform, data = match.data(matched.data), weights = weights)
	ests<- coeftest(fit1, vcov. = vcovCL, cluster = ~subclass)

	estimates[count,c("estimate")] <-lm.beta.match(MOD=ests, dta=censo_ag_wreform_tev, y="SugarCane_Yield")
	estimates[count,c("ses")] <- lm.beta.ses.match(MOD=ests, dta=censo_ag_wreform_tev, y="SugarCane_Yield")

	estimates[count,c("y_var")] <- "Sugar Cane Yield"
	estimates[count,c("est_method")] <- paste0("Matching: ",
	case_when(m=="optimal" ~ "Optimal",
	m=="nearest" ~ "Nearest Neighbor",
	m=="full" ~ "Full",
	m=="cem" ~ "Coarse Exact"),
	" Matching")
	count <- count + 1

	# Coffee
	fit1 <- lm(Coffee_Yield ~ reform, data = match.data(matched.data), weights = weights)
	ests<- coeftest(fit1, vcov. = vcovCL, cluster = ~subclass)

	estimates[count,c("estimate")] <-lm.beta.match(MOD=ests, dta=censo_ag_wreform_tev, y="Coffee_Yield")
	estimates[count,c("ses")] <- lm.beta.ses.match(MOD=ests, dta=censo_ag_wreform_tev, y="Coffee_Yield")

	estimates[count,c("y_var")] <- "Coffee Yield"
	estimates[count,c("est_method")] <- paste0("Matching: ",
	case_when(m=="optimal" ~ "Optimal",
	m=="nearest" ~ "Nearest Neighbor",
	m=="full" ~ "Full",
	m=="cem" ~ "Coarse Exact"),
	" Matching")
	count <- count + 1

	# Staple Crop Share
	fit1 <- lm(StapleCrop_Share ~ reform, data = match.data(matched.data), weights = weights)
	ests<- coeftest(fit1, vcov. = vcovCL, cluster = ~subclass)

	estimates[count,c("estimate")] <-lm.beta.match(MOD=ests, dta=censo_ag_wreform_tev, y="StapleCrop_Share")
	estimates[count,c("ses")] <- lm.beta.ses.match(MOD=ests, dta=censo_ag_wreform_tev, y="StapleCrop_Share")

	estimates[count,c("y_var")] <- "Staple Crop Share"
	estimates[count,c("est_method")] <- paste0("Matching: ",
	case_when(m=="optimal" ~ "Optimal",
	m=="nearest" ~ "Nearest Neighbor",
	m=="full" ~ "Full",
	m=="cem" ~ "Coarse Exact"),
	" Matching")
	count <- count + 1

	# Maize
	fit1 <- lm(Maize_Yield ~ reform, data = match.data(matched.data), weights = weights)
	ests<- coeftest(fit1, vcov. = vcovCL, cluster = ~subclass)

	estimates[count,c("estimate")] <-lm.beta.match(MOD=ests, dta=censo_ag_wreform_tev, y="Maize_Yield")
	estimates[count,c("ses")] <- lm.beta.ses.match(MOD=ests, dta=censo_ag_wreform_tev, y="Maize_Yield")

	estimates[count,c("y_var")] <- "Maize Yield"
	estimates[count,c("est_method")] <- paste0("Matching: ",
	case_when(m=="optimal" ~ "Optimal",
	m=="nearest" ~ "Nearest Neighbor",
	m=="full" ~ "Full",
	m=="cem" ~ "Coarse Exact"),
	" Matching")
	count <- count + 1

	# Beans
	fit1 <- lm(Beans_Yield ~ reform, data = match.data(matched.data), weights = weights)
	ests<- coeftest(fit1, vcov. = vcovCL, cluster = ~subclass)

	estimates[count,c("estimate")] <-lm.beta.match(MOD=ests, dta=censo_ag_wreform_tev, y="Beans_Yield")
	estimates[count,c("ses")] <- lm.beta.ses.match(MOD=ests, dta=censo_ag_wreform_tev, y="Beans_Yield")

	estimates[count,c("y_var")] <- "Beans Yield"
	estimates[count,c("est_method")] <- paste0("Matching: ",
	case_when(m=="optimal" ~ "Optimal",
	m=="nearest" ~ "Nearest Neighbor",
	m=="full" ~ "Full",
	m=="cem" ~ "Coarse Exact"),
	" Matching")
	count <- count + 1

	# Revenues:
	fit1 <- lm(ln_agprod ~ reform, data = match.data(matched.data), weights = weights)
	ests<- coeftest(fit1, vcov. = vcovCL, cluster = ~subclass)

	estimates[count,c("estimate")] <-lm.beta.match(MOD=ests, dta=censo_ag_wreform_tev, y="ln_agprod")
	estimates[count,c("ses")] <- lm.beta.ses.match(MOD=ests, dta=censo_ag_wreform_tev, y="ln_agprod")

	estimates[count,c("y_var")] <- "Revenues per ha"
	estimates[count,c("est_method")] <- paste0("Matching: ",
	case_when(m=="optimal" ~ "Optimal",
	m=="nearest" ~ "Nearest Neighbor",
	m=="full" ~ "Full",
	m=="cem" ~ "Coarse Exact"),
	" Matching")
	count <- count + 1

	# Profits:
	fit1 <- lm(ln_agprodII ~ reform, data = match.data(matched.data), weights = weights)
	ests<- coeftest(fit1, vcov. = vcovCL, cluster = ~subclass)

	estimates[count,c("estimate")] <-lm.beta.match(MOD=ests, dta=censo_ag_wreform_tev, y="ln_agprodII")
	estimates[count,c("ses")] <- lm.beta.ses.match(MOD=ests, dta=censo_ag_wreform_tev, y="ln_agprodII")

	estimates[count,c("y_var")] <- "Profits per ha"
	estimates[count,c("est_method")] <- paste0("Matching: ",
	case_when(m=="optimal" ~ "Optimal",
	m=="nearest" ~ "Nearest Neighbor",
	m=="full" ~ "Full",
	m=="cem" ~ "Coarse Exact"),
	" Matching")
	count <- count + 1

	# TFP:
	fit1 <- lm(ln_tfp_geo ~ reform, data = match.data(matched.data), weights = weights)
	ests<- coeftest(fit1, vcov. = vcovCL, cluster = ~subclass)

	estimates[count,c("estimate")] <-lm.beta.match(MOD=ests, dta=censo_ag_wreform_tev, y="ln_tfp_geo")
	estimates[count,c("ses")] <- lm.beta.ses.match(MOD=ests, dta=censo_ag_wreform_tev, y="ln_tfp_geo")

	estimates[count,c("y_var")] <- "Farm Productivity"
	estimates[count,c("est_method")] <- paste0("Matching: ",
	case_when(m=="optimal" ~ "Optimal",
	m=="nearest" ~ "Nearest Neighbor",
	m=="full" ~ "Full",
	m=="cem" ~ "Coarse Exact"),
	" Matching")
	count <- count + 1

	}
	}
	estimates

	########################################

	# Clean data for plotting:
	alpha<- 0.05
	Multiplier <- qnorm(1 - alpha / 2)

	Multiplier2 <- qnorm(1 - 2*alpha / 2)

	data <- estimates
	betas <- data
	dim(betas)
	betas<- betas[seq(dim(betas)[1],1),]

	# Create Matrix for plotting:
	MatrixofModels <- betas[c("y_var", "estimate","ses","est_method")]
	colnames(MatrixofModels) <- c("Outcome", "Estimate", "StandardError", "Method")
	MatrixofModels$Outcome <- factor(MatrixofModels$Outcome, levels = unique(MatrixofModels$Outcome))

	# Re-Order for plotting:
	MatrixofModels$Outcome <- factor(MatrixofModels$Outcome,
	levels = c("Cash Crop Share",
	"Coffee Yield",
	"Sugar Cane Yield",
	"Staple Crop Share",
	"Maize Yield",
	"Beans Yield",
	"Revenues per ha",
	"Profits per ha",
	"Farm Productivity"))

	# Plot:
	OutputPlot <- qplot(Method, Estimate, ymin = Estimate - Multiplier * StandardError,
	ymax = Estimate + Multiplier * StandardError, data = MatrixofModels, geom = "pointrange",
	ylab = NULL, xlab = NULL, facets=~ Outcome, alpha=0.5)

	OutputPlot <- ggplot() + geom_errorbar(aes(x=Method, y=Estimate, ymin = Estimate - Multiplier * StandardError,
	ymax = Estimate + Multiplier * StandardError), data = MatrixofModels,
	size=0.6,
	width=0,
	alpha=0.5,
	col="black") +
	geom_point(aes(x=Method, y=Estimate), data = MatrixofModels,
	col="black",show.legend = FALSE) + facet_wrap(~Outcome)


	OutputPlot <- OutputPlot + geom_hline(yintercept = 0, lwd = I(7/12), colour = I(hsv(0/12, 7/12, 7/12)), alpha = I(5/12))
	OutputPlot <- OutputPlot + theme_bw() + ylab("\nStandardized Effect") + aesthetics
	# Add 90%
	OutputPlot <- OutputPlot + geom_errorbar(aes(x=Method, y=Estimate, ymin = Estimate - Multiplier2 * StandardError,
	ymax = Estimate + Multiplier2 * StandardError), data = MatrixofModels,
	size=0.5,
	width=0,
	col="black",show.legend = FALSE)
	OutputPlot <- OutputPlot + geom_point(aes(x=Method, y=Estimate), data = MatrixofModels,
	col="black",show.legend = FALSE)
	# Save:
	OutputPlot + coord_flip() + scale_y_continuous(breaks = seq(-2, 1.5,0.5)) +
	xlab("") +
	coord_flip(ylim= c(-2,1.5))
	ggsave(filename="./Output/CoefPlot_Matching.pdf", scale=1.25)