--- title: 'Exploring Emission Factors' date: "`r Sys.Date()`" output: rmarkdown::html_vignette urlcolor: blue vignette: > %\VignetteIndexEntry{Exploring Emission Factors} \usepackage[utf8]{inputenc} %\VignetteEngine{knitr::rmarkdown} editor_options: markdown: wrap: 72 --- ```{r, include = FALSE} knitr::opts_chunk$set( collapse = TRUE, comment = "#>") ``` Emission factor models tell us the mass of pollutants that are expected to be emitted by a given vehicle given a few characteristics such as vehicle age, type, fuel, technology, speed, and distance traveled. Various environmental agencies develop these functional relations based on data collected from local measurements. Understanding how emission factor data work is very important to understand how the emission estimates of a given vehicle or public transport system are influenced by the methodological choices of which emission factor model should be used. This vignette helps users explore the emission factors data available in the `gtfs2emis` package. ## Available emission factor models The `gtfs2emis` package currently includes hot-exhaust emission factor data from four environmental agencies. Reports with detailed information and methods on how these emission factor data were originally calculated can be found on the agencies' websites in the links below ***Hot-exhaust emissions*** \- Brazil, Environment Company of Sao Paulo --- [CETESB](https://cetesb.sp.gov.br/veicular/) \- United States, Environmental Protection Agency --- [MOVES3 Model](https://www.epa.gov/moves) \- United States, California Air Resources Board --- [EMFAC2017 model](https://arb.ca.gov/emfac/emissions-inventory) \- Europe, European Environment Agency --- [EMEP-EEA](https://www.eea.europa.eu//publications/emep-eea-guidebook-2019) ***Wear emissions (tire, brake and road wear)*** \- Europe, European Environment Agency --- [EMEP-EEA](https://www.eea.europa.eu//publications/emep-eea-guidebook-2019) ## Visualizing emission factor data Emission fator values vary by fleet characteristics --- as shown in [Defining Fleet data vignette](https://ipeagit.github.io/gtfs2emis/articles/gtfs2emis_fleet_data.html). In this section we will use the `ef_europe_emep()` function and look at three types of urban buses (Midi, Standard and Articulated) to illustrate how emissions vary according to vehicle type, average speed, and pollutant. ```{r, message = FALSE, echo = FALSE} #library(devtools) #devtools::load_all() ``` ```{r, eval = FALSE,message = FALSE,} #library(gtfs2emis) ``` ```{r, message = FALSE} library(units) library(gtfs2emis) library(ggplot2) ef_europe <- ef_europe_emep(speed = units::set_units(10:100,"km/h") ,veh_type = c("Ubus Midi <=15 t" ,"Ubus Std 15 - 18 t" ,"Ubus Artic >18 t") ,euro = c("III", "IV", "V") ,pollutant = c("PM10", "NOx") ,fuel = c("D", "D", "D") ,tech = c("-", "SCR", "SCR") ,as_list = TRUE) names(ef_europe) ``` In the case above, the function returns a `list` that contains all the relevant information for the emission factor --- shown in `names(ef_europe)`. However, it may be useful to check the emission factor results in a `data.frame` or graphic format. ```{r} ef_europe_dt <- emis_to_dt(emi_list = ef_europe ,emi_vars = "EF" ,veh_vars = c("veh_type","euro","fuel","tech") ,pol_vars = "pollutant" ,segment_vars = c("slope","load","speed")) head(ef_europe_dt) ``` Plotting the speed-dependent emission factors according to vehicle type (`veh_type`) and euro standard (`euro`). ```{r, fig.height=4, fig.width=7} ef_europe_dt$name_fleet <- paste(ef_europe_dt$veh_type, "/ Euro" , ef_europe_dt$euro) # plot ggplot(ef_europe_dt) + geom_line(aes(x = speed,y = EF,color = name_fleet))+ labs(color = "Category / EURO")+ facet_wrap(~pollutant,scales = "free")+ theme(legend.position = "bottom") ``` There are situations where the emission factor are not available for a given input parameter. In the case of `ef_europe_emep()` function, when the information on vehicle technology does not match the existing database, the package displays a message indicating the technology considered. Please check the message shown in the code block below. In such case, users can either select existing data for the combining variables (`euro`, `tech`, `veh_type`, and `pollutant`), or accept the assumed change in vehicle technology. ```{r} ef_europe_co2 <- ef_europe_emep(speed = units::set_units(10:100,"km/h") ,veh_type = "Ubus Std 15 - 18 t" ,euro = "VI",pollutant = "CO2" ,tech = "DPF+SCR" ,as_list = TRUE) ``` The other EF functions, `ef_usa_emfac()`, `ef_usa_moves()` and `ef_brazil_cetesb()` work in a similar way. See the functions documentation for more detail. ### Scaling Emission Factors: making emission factors speed-dependent For most models (MOVES3, EMEP-EEA and EMFAC2017), emission factors depend on a vehicle's speed. However, the emission factors developed for Brazil by CETESB (`ef_brazil_cetesb()`) do not vary by vehicle speed. In such a case, users can "scale" or adjust the local emission factor values to make them speed-dependent using the function `ef_scaled_euro()`. When using the EMEP-EEA model as a reference, the scaled emission factor varies according to vehicle's speed following the expression: $$ EF_{scaled} (V) = EF_{local} * \frac{EF_{euro}(V)}{EF_{euro}(SDC)}, $$ where $EF_{scaled}(V)$ is the scaled emission factor for each street link, $EF_{local}$ is the local emission factor, $EF_{euro}(V)$ and $EF_{euro}(SDC)$ are the EMEP/EEA emission factor the speed of V and the average urban driving speed SDC, respectively. The scaled behavior of EF can be verified graphically when we plot the $EF_{local}$, $EF_{scaled}(V)$, and the $EF_{euro}(V)$ that is used as the reference To plot these data, we need six quick steps: 1) Build a `data.frame` of fleet indicating the correspondence between the fleet characteristic in the local and European emission models ```{r} fleet_filepath <- system.file("extdata/bra_cur_fleet.txt", package = "gtfs2emis") cur_fleet <- read.table(fleet_filepath,header = TRUE, sep = ",", nrows = 1) cur_fleet ``` 2) Estimate local emission factors ```{r} cur_local_ef <- ef_brazil_cetesb(pollutant = "CO2" ,veh_type = cur_fleet$type_name_br ,model_year = cur_fleet$year) head(cur_local_ef) # convert Local EF to data.frame cur_local_ef_dt <- emis_to_dt(emi_list = cur_local_ef ,emi_vars = "EF") ``` 3) Estimate `ef_emep_europe` ```{r} # Euro EF cur_euro_ef <- ef_europe_emep(speed = units::set_units(10:100,"km/h") ,veh_type = cur_fleet$veh_type ,euro = cur_fleet$euro ,pollutant = "CO2" ,tech = "-" ) # convert to data.frame cur_euro_ef_dt <- emis_to_dt(emi_list = cur_euro_ef ,emi_vars = "EF" ,veh_vars = c("veh_type","euro","fuel","tech") ,segment_vars = "speed") cur_euro_ef_dt$source <- "Euro EF" ``` 4) Apply `ef_scaled_euro()` ```{r} cur_scaled_ef <- ef_scaled_euro(ef_local = cur_local_ef$EF ,speed = units::set_units(10:100,"km/h") ,veh_type = cur_fleet$veh_type ,euro = cur_fleet$euro ,pollutant = "CO2" ,tech = "-" ) # convert to data.frame cur_scaled_ef_dt <- emis_to_dt(emi_list = cur_scaled_ef ,emi_vars = "EF" ,veh_vars = c("veh_type","euro","fuel","tech") ,segment_vars = "speed") cur_scaled_ef_dt$source <- "Scaled EF" ``` 5) View in ggplot2 ```{r, fig.width=6, fig.height=5} # rbind data cur_ef <- rbind(cur_euro_ef_dt, cur_scaled_ef_dt) cur_ef$source <- factor(cur_ef$source ,levels = c("Scaled EF", "Euro EF")) # plot ggplot() + # add scaled and euro EF geom_line(data = cur_ef ,aes(x = speed,y = EF ,group = source,color = source))+ # add local EF geom_hline(aes(yintercept = cur_local_ef_dt$EF) ,colour = "black",linetype="dashed") + geom_point(aes(x = units::set_units(19,'km/h') ,y = cur_local_ef$EF)) + # add local EF text geom_text(aes(x = units::set_units(19,'km/h') , y = cur_local_ef_dt$EF) ,label = sprintf('Local EF = %s g/km at 19 km/h',round(cur_local_ef_dt$EF,1)) ,hjust = 0,nudge_y = 100,nudge_x = 1 ,size = 3,fontface = 1)+ # configs plots scale_color_manual(values=c("red","blue"))+ coord_cartesian(ylim = c(0,max(cur_scaled_ef_dt$EF)))+ labs(color = NULL) ``` In this case, the `scaled_EF` has the same value of `local_EF` (dashed line) when `speed = 19` km/h, and a similar decaying behavior as `Euro_EF` as speed decreases. ## Checking `gtfs2emis` imported data Users can have a closer look to the hot-exhaust emission factor data included in the package by using the following functions: - `data(ef_brazil_cetesb)` from Environment Company of Sao Paulo, Brazil (CETESB) - `data(ef_usa_moves)` from MOtor Vehicle Emission Simulator (MOVES) - `data(ef_usa_emfac)` from California Air Resources Board (EMFAC Model) - `data(ef_europe_emep)` from European Environment Agency (EMEP/EEA) The data presented on the agencies website and software was downloaded and pre-processed in `gtfs2emis` to be easily read by the emission factor functions. Users can also access the scripts used to process raw data in the [gtfs2emis GitHub repository](https://github.com/ipeaGIT/gtfs2emis/tree/master/data-raw). ## Learn more Check out our extra guides: - [Exploring Non-Exhaust Emission Factors](https://ipeagit.github.io/gtfs2emis/articles/gtfs2emis_non_exhaust_ef.html) ## Report a bug If you have any suggestions or want to report an error, please visit [the package GitHub page](https://github.com/ipeaGIT/gtfs2emis/issues).