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| rm(list = ls()) |
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| require(foreign) |
| require(ggplot2) |
| require(rgdal) |
| require(rgeos) |
| require(RColorBrewer) |
| require(maptools) |
| require(scales) |
| require(gridExtra) |
| require(plyr) |
| require(dplyr) |
| require(mapproj) |
| require(raster) |
| require(ggvis) |
| require(rdrobust) |
| require(stringdist) |
| require(gdata) |
| require(rdd) |
| require(stargazer) |
| require(haven) |
| require(readstata13) |
| require(lfe) |
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| censo_ag_wreform <- read.dta13(file="Data/censo_ag_wreform.dta") |
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| aesthetics <- list( |
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| coord_equal(), |
| theme_bw(), |
| theme( |
| text=element_text(family="Palatino"), |
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| panel.grid.minor=element_blank(), |
| panel.grid.major=element_blank(), |
| axis.line=element_blank(), |
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| axis.text.x=element_text(angle=45, hjust=1,size=11,face="bold"))) |
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| fao_es_grains <- read.csv(file="Data/Prices/FAO_Price_Data/data_table_GIEWSFPMATOOL.csv",header=TRUE) |
| fao_es_coffee <- read.csv(file="Data/Prices/FAO_Price_Data/FAOSTAT_data_5-21-2017-Coffee.csv",header=TRUE) |
| fao_sugarcane <- read.csv(file="Data/Prices/FAO_Price_Data/SugarPrices.csv",header=TRUE) |
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| mag_es_sugarcane <- read.csv(file="Data/Prices/MAG/RETROSPECTIVA DE PRECIOS DE AZUCAR.csv",header=TRUE) |
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| mag_es_maize <- read.csv(file="Data/Prices/MAG/RETROSPECTIVA DE GRANOS BASICOS 2001-2017 - Maiz.csv",header=TRUE) |
| mag_es_rice <- read.csv(file="Data/Prices/MAG/RETROSPECTIVA DE GRANOS BASICOS 2001-2017 - Arroz.csv",header=TRUE) |
| mag_es_sorghum <- read.csv(file="Data/Prices/MAG/RETROSPECTIVA DE GRANOS BASICOS 2001-2017 - Maicillo.csv",header=TRUE) |
| mag_es_beansI <- read.csv(file="Data/Prices/MAG/RETROSPECTIVA DE GRANOS BASICOS 2001-2017 - Frijol Rojo de Seda.csv",header=TRUE) |
| mag_es_beans <- read.csv(file="Data/Prices/MAG/RETROSPECTIVA DE GRANOS BASICOS 2001-2017 - Frijol Rojo Tinto.csv",header=TRUE) |
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| csc_es_coffee <- read.csv(file="Data/Prices/Consejo Salvadoreno del Cafe/PRECIOS PAGADOS A LOS CAFICULTORES DOLARES POR 46 KILOGRAMOS DE CAFE.csv",header=TRUE) |
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| coffee_prices <- dplyr::select(csc_es_coffee, Year = ANO, Coffee_Price = ANUAL) |
| coffee_prices <- filter(coffee_prices, !is.na(Year)) |
| coffee_prices <- mutate(coffee_prices, Coffee_Price2 = Coffee_Price, Coffee_Price = Coffee_Price/0.46) |
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| |
| sugar_cane_prices <- filter(mag_es_sugarcane, Columna1 == "MAYORISTA (QQ)") |
| sugar_cane_prices <- dplyr::select(sugar_cane_prices, Year = ANO, Sugar_Cane_Price = PROMEDIO) |
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| fao_sugarcane_prices <- dplyr::select(fao_sugarcane, Year, Month, Monthly_Price = INTERNATIONAL.PRICES..Export..ICE.futures.US..Sugar..US.Dollar.kg) |
| fao_sugarcane_prices <- mutate(fao_sugarcane_prices, Monthly_Price = Monthly_Price*46) |
| fao_sugarcane_prices <- summarise(group_by(fao_sugarcane_prices, Year), Intl_Sugar_Cane_Price = mean(Monthly_Price)) |
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| maize_prices <- dplyr::select(mag_es_maize, Year = ANO, Maize_Price = PROMEDIO) |
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| bean_prices <- dplyr::select(mag_es_beans, Year = ANO, Beans_Price = PROMEDIO) |
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| prices <- left_join(coffee_prices,sugar_cane_prices, by="Year") |
| prices <- left_join(prices,maize_prices, by="Year") |
| prices <- left_join(prices,bean_prices, by="Year") |
| prices <- left_join(prices,fao_sugarcane_prices, by="Year") |
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| prices |
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| 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$bws["h","right"] ) |
| sx <- sd(model.dta[,c("Above500")]) |
| |
| sy <- sd((model.dta[,c(y)]),na.rm=TRUE) |
| beta <- b * sx/sy |
| return(beta) |
| } |
| lm.beta.ses <- function (MOD, dta,y="ln_agprod") |
| { |
| b <- MOD$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")]) |
| |
| 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 |
| x[ x > lim[2] ] <- NA |
| 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] |
| x[ x > lim[2] ] <- lim[2] |
| 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 |
| } |
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| |
| years <- 2005:2015 |
| rd_estimates <-data.frame(Year = years, |
| ln_agprod_estimates = rep(0, length(years)), ln_agprod_ses = rep(0, length(years)), |
| ln_laborprod_estimates = rep(0, length(years)), ln_laborprod_ses = rep(0, length(years))) |
| censo_ag_wreform_tev <- censo_ag_wreform |
|
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| for (i in years) { |
| |
| censo_ag_wreform_tev <- mutate(censo_ag_wreform_tev, |
| agrev=ifelse(is.na(Maize_Yield),0,Maize_Yield)*Area_has*prices[prices$Year==i,c("Maize_Price")] + |
| ifelse(is.na(Beans_Yield),0,Beans_Yield)*Area_has*prices[prices$Year==i,c("Beans_Price")] + |
| ifelse(is.na(Coffee_Yield),0,Coffee_Yield)*Area_has*10*prices[prices$Year==i,c("Coffee_Price")] + |
| ifelse(is.na(SugarCane_Yield),0,SugarCane_Yield)*Area_has*prices[prices$Year==i,c("Intl_Sugar_Cane_Price")]) |
|
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| censo_ag_wreform_tev <- filter(censo_ag_wreform_tev, agrev != 0 & !is.na(agrev)) |
| censo_ag_wreform_tev <- mutate(censo_ag_wreform_tev, |
| agprod=agrev/Area_has) |
| |
| |
| censo_ag_wreform_tev <- mutate(censo_ag_wreform_tev, ln_agprod = log(agprod)) |
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| summary(censo_ag_wreform_tev$ln_agprod) |
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| rdests <- rdrobust(y = (censo_ag_wreform_tev$ln_agprod), x=censo_ag_wreform_tev$norm_dist, cluster=censo_ag_wreform_tev$Expropretario_ISTA,vce="hc1") |
| rd_estimates[rd_estimates$Year==i,c("ln_agprod_estimates")] <- lm.beta(MOD=rdests, dta=censo_ag_wreform_tev, y="ln_agprod") |
| rd_estimates[rd_estimates$Year==i,c("ln_agprod_ses")] <-lm.beta.ses(MOD=rdests, dta=censo_ag_wreform_tev, y="ln_agprod") |
| } |
| rd_estimates |
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| ggplot(data = rd_estimates, aes(Year,ln_agprod_estimates)) + |
| geom_line(col="black", size=1) + geom_point(size=2.5) + |
| geom_hline(yintercept = 0, col="red",linetype="dotted", size=0.75) + |
| geom_ribbon(data=rd_estimates,aes(ymin=ln_agprod_estimates - 1.96*ln_agprod_ses,ymax=ln_agprod_estimates + 1.96*ln_agprod_ses, x=Year),alpha=0.15) + |
| aesthetics + ylab("Estimated Effect:\nRevenue per Hectare") + coord_equal(ylim=c(-1, 1)) + |
| scale_x_continuous(breaks=c(years)) + scale_y_continuous(breaks=seq(1,-1, by=-0.25)) + xlab("Year of Price Data Used") |
| ggsave(filename = "./Output/TemporalEV_LnAgProd.pdf") |
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| coffee_prices <- dplyr::select(csc_es_coffee, Year = ANO, Coffee_Price = ANUAL) |
| coffee_prices <- filter(coffee_prices, !is.na(Year)) |
| coffee_prices <- mutate(coffee_prices, Coffee_Price = Coffee_Price) |
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| |
| years <- 2005:2015 |
| rd_estimates <-data.frame(Year = years, |
| ln_agprod_estimates = rep(0, length(years)), ln_agprod_ses = rep(0, length(years)), |
| ln_laborprod_estimates = rep(0, length(years)), ln_laborprod_ses = rep(0, length(years))) |
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| for (i in years) { |
| |
| censo_ag_wreform_tev <- mutate(censo_ag_wreform_tev, |
| agrev=ifelse(is.na(Maize_Yield),0,Maize_Yield)*Area_has*prices[prices$Year==i,c("Maize_Price")] + |
| ifelse(is.na(Beans_Yield),0,Beans_Yield)*Area_has*prices[prices$Year==i,c("Beans_Price")] + |
| ifelse(is.na(Coffee_Yield),0,Coffee_Yield)*Area_has*10*prices[prices$Year==i,c("Coffee_Price")] + |
| ifelse(is.na(SugarCane_Yield),0,SugarCane_Yield)*Area_has*prices[prices$Year==i,c("Intl_Sugar_Cane_Price")]) |
|
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| |
| censo_ag_wreform_tev <- filter(censo_ag_wreform_tev, agrev != 0) |
| censo_ag_wreform_tev <- mutate(censo_ag_wreform_tev, |
| agprod=(agrev)/Area_has - ag_prod_cost_wolabor) |
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| censo_ag_wreform_tev <- mutate(censo_ag_wreform_tev, ln_agprod = log(agprod)) |
| summary(censo_ag_wreform_tev$ln_agprod) |
| summary(censo_ag_wreform_tev$ln_laborprod) |
| |
| rdests <- rdrobust(y = (censo_ag_wreform_tev$ln_agprod), x=censo_ag_wreform_tev$norm_dist, cluster=censo_ag_wreform_tev$Expropretario_ISTA,vce="hc1") |
| rd_estimates[rd_estimates$Year==i,c("ln_agprod_estimates")] <- lm.beta(MOD=rdests, dta=censo_ag_wreform_tev, y="ln_agprod") |
| rd_estimates[rd_estimates$Year==i,c("ln_agprod_ses")] <-lm.beta.ses(MOD=rdests, dta=censo_ag_wreform_tev, y="ln_agprod") |
| |
| } |
| rd_estimates |
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| ggplot(data = rd_estimates, aes(Year,ln_agprod_estimates)) + |
| geom_line(col="black", size=1) + geom_point(size=2.5) + |
| geom_hline(yintercept = 0, col="red",linetype="dotted", size=0.75) + |
| geom_ribbon(data=rd_estimates,aes(ymin=ln_agprod_estimates - 1.96*ln_agprod_ses,ymax=ln_agprod_estimates + 1.96*ln_agprod_ses, x=Year),alpha=0.15) + |
| aesthetics + ylab("Estimated Effect:\nProfits per Hectare") + coord_equal(ylim=c(-1, 1)) + |
| scale_x_continuous(breaks=c(years)) + scale_y_continuous(breaks=seq(1,-1, by=-0.25)) + xlab("Year of Price Data Used") |
| ggsave(filename = "./Output/TemporalEV_LnAgProdII.pdf") |
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| years <- 2005:2015 |
| rd_estimates <-data.frame(Year = years, |
| ln_agprod_estimates = rep(0, length(years)), ln_agprod_ses = rep(0, length(years)), |
| ln_laborprod_estimates = rep(0, length(years)), ln_laborprod_ses = rep(0, length(years)), |
| ln_tfp_geo_estimates = rep(0, length(years)), ln_tfp_geo_ses = rep(0, length(years))) |
| censo_ag_wreform_tev <- censo_ag_wreform_tev |
| |
| for (i in years) { |
| |
| censo_ag_wreform_tev <- mutate(censo_ag_wreform_tev, |
| agrev=ifelse(is.na(Maize_Yield),0,Maize_Yield)*Area_has*prices[prices$Year==i,c("Maize_Price")] + |
| ifelse(is.na(Beans_Yield),0,Beans_Yield)*Area_has*prices[prices$Year==i,c("Beans_Price")] + |
| ifelse(is.na(Coffee_Yield),0,Coffee_Yield)*Area_has*10*prices[prices$Year==i,c("Coffee_Price")] + |
| ifelse(is.na(SugarCane_Yield),0,SugarCane_Yield)*Area_has*prices[prices$Year==i,c("Intl_Sugar_Cane_Price")]) |
| |
|
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| censo_ag_wreform_tev <- filter(censo_ag_wreform_tev, agrev != 0) |
| censo_ag_wreform_tev <- mutate(censo_ag_wreform_tev, |
| agprod=(agrev)/Area_has - ag_prod_cost_wolabor) |
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| censo_ag_wreform_tev <- mutate(censo_ag_wreform_tev, ln_agprod = log(agprod), |
| ln_rev = log(agrev/Area_has), |
| ln_rev =winsor(ln_rev, fraction = 0.015), |
| ln_land = log(Area_has), |
| canton_land_suit = ifelse(is.na(canton_land_suit),0,canton_land_suit)) |
|
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| |
| censo_ag_wreform_tev$ln_tfp_geo[which(!is.na(censo_ag_wreform_tev$canton_mean_rain) |
| & !is.na(censo_ag_wreform_tev$ln_land))] <- residuals(felm(ln_rev ~ ln_Total_AgEmpl + ln_land + canton_mean_rain + canton_elev_dem_30sec + canton_land_suit | DEPID | 0 | Expropretario_ISTA, data=censo_ag_wreform_tev)) |
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| rdests <- rdrobust(y = (censo_ag_wreform_tev$ln_tfp_geo), x=censo_ag_wreform_tev$norm_dist, cluster=censo_ag_wreform_tev$Expropretario_ISTA,vce="hc1") |
| rd_estimates[rd_estimates$Year==i,c("ln_tfp_geo_estimates")] <- lm.beta(MOD=rdests, dta=censo_ag_wreform_tev, y="ln_tfp_geo") |
| rd_estimates[rd_estimates$Year==i,c("ln_tfp_geo_ses")] <-lm.beta.ses(MOD=rdests, dta=censo_ag_wreform_tev, y="ln_tfp_geo") |
| } |
| rd_estimates |
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| ggplot(data = rd_estimates, aes(Year,ln_tfp_geo_estimates)) + |
| geom_line(col="black", size=1) + geom_point(size=2.5) + |
| geom_hline(yintercept = 0, col="red",linetype="dotted", size=0.75) + |
| geom_ribbon(data=rd_estimates,aes(ymin=ln_tfp_geo_estimates - 1.96*ln_tfp_geo_ses,ymax=ln_tfp_geo_estimates + 1.96*ln_tfp_geo_ses, x=Year),alpha=0.15) + |
| aesthetics + ylab("Estimated Effect:\nFarm Productivity") + coord_equal(ylim=c(-1, 1)) + |
| scale_x_continuous(breaks=c(years)) + scale_y_continuous(breaks=seq(1,-1, by=-0.25)) + xlab("Year of Price Data Used") |
| ggsave(filename = "./Output/TemporalEV_LnTFP.pdf") |
| |
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