--- title: "IPCC Methodology Tiers in cowfootR" output: rmarkdown::html_vignette vignette: > %\VignetteIndexEntry{IPCC Methodology Tiers in cowfootR} %\VignetteEngine{knitr::rmarkdown} %\VignetteEncoding{UTF-8} --- ```{r setup, include = FALSE} knitr::opts_chunk$set( fig.alt = "Figure generated by this vignette; see the surrounding text for details.", collapse = TRUE, comment = "#>", fig.width = 8, fig.height = 6, warning = FALSE, message = FALSE ) library(cowfootR) library(ggplot2) library(dplyr) library(knitr) if (!requireNamespace("tidyr", quietly = TRUE)) { stop("This vignette requires 'tidyr'. Please install it with install.packages('tidyr').") } ``` # Understanding IPCC Methodology Tiers The Intergovernmental Panel on Climate Change (IPCC) provides three tiers of methodological complexity for greenhouse gas inventory calculations. cowfootR implements Tier 1 and Tier 2 methodologies for dairy farm carbon footprint assessments. This vignette explains the differences, when to use each approach, and demonstrates their practical application. ## Data Requirements Analysis ### Tier 1 Data Needs ```{r} tier1_requirements <- data.frame( Category = c("Animal Data", "Production", "Management", "Optional"), Essential_Data = c( "Number by category (cows, heifers, calves)", "Annual milk production (litres)", "Manure system type, basic inputs", "Farm area, country location" ), Time_to_Collect = c("< 1 hour", "< 1 hour", "1-2 hours", "< 1 hour"), Data_Source = c("Farm records", "Milk processor", "Farmer interview", "Farm records") ) kable(tier1_requirements, caption = "Tier 1 Data Requirements") ``` ### Tier 2 Additional Requirements ```{r} tier2_additional <- data.frame( Category = c("Animal Characteristics", "Nutrition", "Management Detail", "Environmental"), Additional_Data = c( "Body weights, milk yield per cow, breeding records", "Feed composition, DM intake, diet digestibility", "Precise input quantities, equipment usage", "Climate data, soil types, system temperatures" ), Time_to_Collect = c("2-4 hours", "4-8 hours", "2-4 hours", "1-2 hours"), Expertise_Level = c("Basic", "Intermediate", "Basic", "Basic") ) kable(tier2_additional, caption = "Additional Tier 2 Data Requirements") ``` ## Input columns used by `calc_batch()` for Tier 2 calculations When using `calc_batch()` with `tier = 2`, users may provide additional farm-level variables to enable more detailed IPCC Tier 2 calculations. All inputs represent one accounting year unless explicitly stated otherwise by the column name (e.g., *_kg_day). The input data frame is flexible: only a small set of columns is strictly required, while the presence of additional columns enables more refined calculations. Missing optional columns do not cause errors; instead, cowfootR falls back to Tier 1–consistent default assumptions following IPCC and IDF guidance. ### Core required columns (all tiers) - `FarmID`: Unique farm identifier - `Milk_litres`: Annual milk production (litres/year) - `Cows_milking`: Number of milking cows - `Area_total_ha`: Total managed farm area (hectares) ### Tier 2–relevant optional columns by emission source #### Enteric fermentation (Tier 2 refinement) Providing one or more of the following columns enables Tier 2 enteric methane calculations based on animal performance and intake: - `Milk_yield_kg_cow_year`: Average annual milk yield per cow (kg/year) - `Body_weight_cows_kg`: Average body weight of milking cows (kg) - `MS_intake_cows_milking_kg_day`: Dry matter intake of milking cows (kg/day) - `Ym_percent`: Methane conversion factor (% of gross energy intake) If none of these variables are provided, Tier 1 default emission factors are used. #### Young stock (optional refinement) When young stock is included, Tier 2 calculations may also use: - `Body_weight_heifers_kg` - `Body_weight_calves_kg` - `Body_weight_bulls_kg` - `MS_intake_heifers_kg_day` - `MS_intake_calves_kg_day` - `MS_intake_bulls_kg_day` #### Manure management (Tier 2 refinement) Tier 2 manure emissions may use additional information when available: - `Manure_system`: Manure management system (e.g., pasture, liquid storage) - `Diet_digestibility`: Diet digestibility (fraction) - `Protein_intake_kg_day`: Average protein intake per animal (kg/day) - `Retention_days`: Manure storage or retention time (days) - `System_temperature`: Average system temperature (°C) - `Climate_zone`: Climatic classification used for emission factors #### Other emission sources Soil, energy, and input-related emissions primarily rely on annual activity data (e.g., fertilizer use, fuel consumption, purchased inputs). For these sources, Tier 2 calculations are typically driven by regional emission factors rather than additional farm-specific columns. ### Complete column specification The full and authoritative list of supported input columns, including expected units and naming conventions, is provided by the Excel template generated with: ```{r} cf_download_template() ``` ## Theoretical Background ### IPCC Tier System Overview The IPCC tier system balances accuracy with data requirements and complexity: - **Tier 1**: Default emission factors with basic activity data - **Tier 2**: Country/region-specific factors with detailed activity data - **Tier 3**: Advanced modeling with comprehensive measurements (not implemented in cowfootR) ### Key Differences in Dairy Applications | Aspect | Tier 1 | Tier 2 | |--------|--------|--------| | **Emission Factors** | IPCC default values | Region/farm-specific values | | **Data Requirements** | Basic (animal numbers, production) | Detailed (weights, intake, composition) | | **Expected precision** | Lower (screening-level) | Higher (farm-specific when good data are available) | | **Time Investment** | Low (hours) | Medium (days) | | **Suitable For** | Screening, regional estimates | Farm management, policy | ## Methodological Differences by Emission Source ### Enteric Fermentation #### Tier 1 Approach - Uses fixed emission factors by animal category and production system - Based on broad regional averages - No consideration of diet quality or animal performance ```{r} # Tier 1 enteric calculation example enteric_tier1 <- calc_emissions_enteric( n_animals = 100, cattle_category = "dairy_cows", production_system = "mixed", tier = 1 # Uses default emission factors ) print(enteric_tier1$emission_factors) ``` #### Tier 2 Approach - Calculates methane based on energy intake and conversion efficiency - Accounts for diet digestibility, animal productivity, and body weight - Uses farm-specific or regional Ym (methane conversion) factors ```{r} # Tier 2 enteric calculation with detailed parameters enteric_tier2 <- calc_emissions_enteric( n_animals = 100, cattle_category = "dairy_cows", avg_milk_yield = 7200, avg_body_weight = 580, dry_matter_intake = 19.5, ym_percent = 6.2, tier = 2 # Uses energy-based calculation ) print(enteric_tier2$emission_factors) ``` ### Manure Management #### Tier 1 vs Tier 2 Comparison ```{r} # Tier 1: Simple emission factors manure_tier1 <- calc_emissions_manure( n_cows = 100, manure_system = "liquid_storage", tier = 1 ) # Tier 2: VS and MCF-based calculation manure_tier2 <- calc_emissions_manure( n_cows = 100, manure_system = "liquid_storage", tier = 2, avg_body_weight = 580, diet_digestibility = 0.68, climate = "temperate", retention_days = 90, system_temperature = 20 ) # Compare results manure_comparison <- data.frame( Tier = c("Tier 1", "Tier 2"), CH4_kg = c(manure_tier1$ch4_kg, manure_tier2$ch4_kg), N2O_kg = c(manure_tier1$n2o_total_kg, manure_tier2$n2o_total_kg), CO2eq_kg = c(manure_tier1$co2eq_kg, manure_tier2$co2eq_kg), Method = c("Default factors", "VS + MCF calculation") ) kable(manure_comparison, caption = "Manure Management: Tier 1 vs Tier 2") ``` ## Comprehensive Farm Comparison Let's compare both tiers using a realistic farm example: ### Farm Profile ```{r} # Define comprehensive farm data farm_profile <- list( # Basic data (required for both tiers) dairy_cows = 120, heifers = 35, calves = 40, milk_production = 850000, # litres/year farm_area = 160, # hectares # Detailed data (enhances Tier 2) cow_body_weight = 580, heifer_body_weight = 380, calf_body_weight = 170, milk_yield_per_cow = 7080, cow_dm_intake = 19.2, heifer_dm_intake = 11.5, calf_dm_intake = 6.2, diet_digestibility = 0.67, ym_factor = 6.1, # Management data concentrate_feed = 195000, # kg/year n_fertilizer = 2200, # kg N/year diesel_use = 9500, # litres/year electricity = 52000 # kWh/year ) print(farm_profile[1:8]) ``` ### Tier 1 Assessment ```{r} # Complete Tier 1 assessment boundaries <- set_system_boundaries("farm_gate") # Tier 1 calculations enteric_t1 <- calc_emissions_enteric( n_animals = farm_profile$dairy_cows, cattle_category = "dairy_cows", tier = 1, boundaries = boundaries ) heifers_t1 <- calc_emissions_enteric( n_animals = farm_profile$heifers, cattle_category = "heifers", tier = 1, boundaries = boundaries ) calves_t1 <- calc_emissions_enteric( n_animals = farm_profile$calves, cattle_category = "calves", tier = 1, boundaries = boundaries ) manure_t1 <- calc_emissions_manure( n_cows = farm_profile$dairy_cows + farm_profile$heifers + farm_profile$calves, manure_system = "pasture", tier = 1, boundaries = boundaries ) soil_t1 <- calc_emissions_soil( n_fertilizer_synthetic = farm_profile$n_fertilizer, n_excreta_pasture = (farm_profile$dairy_cows + farm_profile$heifers) * 100, area_ha = farm_profile$farm_area, boundaries = boundaries ) energy_t1 <- calc_emissions_energy( diesel_l = farm_profile$diesel_use, electricity_kwh = farm_profile$electricity, country = "UY", boundaries = boundaries ) inputs_t1 <- calc_emissions_inputs( conc_kg = farm_profile$concentrate_feed, fert_n_kg = farm_profile$n_fertilizer, boundaries = boundaries ) # Aggregate Tier 1 results enteric_combined_t1 <- list( source = "enteric", co2eq_kg = enteric_t1$co2eq_kg + heifers_t1$co2eq_kg + calves_t1$co2eq_kg ) total_t1 <- calc_total_emissions(enteric_combined_t1, manure_t1, soil_t1, energy_t1, inputs_t1) ``` ### Tier 2 Assessment ```{r} # Complete Tier 2 assessment using detailed data enteric_t2 <- calc_emissions_enteric( n_animals = farm_profile$dairy_cows, cattle_category = "dairy_cows", avg_milk_yield = farm_profile$milk_yield_per_cow, avg_body_weight = farm_profile$cow_body_weight, dry_matter_intake = farm_profile$cow_dm_intake, ym_percent = farm_profile$ym_factor, tier = 2, boundaries = boundaries ) heifers_t2 <- calc_emissions_enteric( n_animals = farm_profile$heifers, cattle_category = "heifers", avg_body_weight = farm_profile$heifer_body_weight, dry_matter_intake = farm_profile$heifer_dm_intake, ym_percent = farm_profile$ym_factor, tier = 2, boundaries = boundaries ) calves_t2 <- calc_emissions_enteric( n_animals = farm_profile$calves, cattle_category = "calves", avg_body_weight = farm_profile$calf_body_weight, dry_matter_intake = farm_profile$calf_dm_intake, tier = 2, boundaries = boundaries ) manure_t2 <- calc_emissions_manure( n_cows = farm_profile$dairy_cows + farm_profile$heifers + farm_profile$calves, manure_system = "pasture", tier = 2, avg_body_weight = 500, # Weighted average diet_digestibility = farm_profile$diet_digestibility, climate = "temperate", boundaries = boundaries ) # Soil and other sources remain the same enteric_combined_t2 <- list( source = "enteric", co2eq_kg = enteric_t2$co2eq_kg + heifers_t2$co2eq_kg + calves_t2$co2eq_kg ) total_t2 <- calc_total_emissions(enteric_combined_t2, manure_t2, soil_t1, energy_t1, inputs_t1) ``` ### Results Comparison ```{r} # Compare tier results tier_comparison <- data.frame( Source = c("Enteric", "Manure", "Soil", "Energy", "Inputs", "TOTAL"), Tier1_kg = c( enteric_combined_t1$co2eq_kg, manure_t1$co2eq_kg, soil_t1$co2eq_kg, energy_t1$co2eq_kg, inputs_t1$total_co2eq_kg, total_t1$total_co2eq ), Tier2_kg = c( enteric_combined_t2$co2eq_kg, manure_t2$co2eq_kg, soil_t1$co2eq_kg, energy_t1$co2eq_kg, inputs_t1$total_co2eq_kg, total_t2$total_co2eq ) ) %>% mutate( Difference_kg = Tier2_kg - Tier1_kg, Difference_pct = round((Tier2_kg - Tier1_kg) / Tier1_kg * 100, 1) ) kable(tier_comparison, caption = "Emission Source Comparison: Tier 1 vs Tier 2") ``` ### Visualization of Differences ```{r fig.width=10, fig.height=6} # Prepare data for visualization comparison_long <- tier_comparison %>% filter(Source != "TOTAL") %>% select(Source, Tier1_kg, Tier2_kg) %>% tidyr::pivot_longer( cols = c(Tier1_kg, Tier2_kg), names_to = "Tier", values_to = "Emissions" ) %>% mutate(Tier = gsub("_kg", "", Tier)) # Create comparison chart ggplot(comparison_long, aes(x = Source, y = Emissions, fill = Tier)) + geom_col(position = "dodge", alpha = 0.8) + geom_text(aes(label = format(round(Emissions), big.mark = ",")), position = position_dodge(width = 0.9), vjust = -0.3, size = 3 ) + labs( title = "Emission Estimates: Tier 1 vs Tier 2 Methodology", subtitle = "Same farm, different calculation approaches", x = "Emission Source", y = "Emissions (kg CO₂eq/year)" ) + theme_minimal() + theme( plot.title = element_text(size = 14, hjust = 0.5), axis.text.x = element_text(angle = 45, hjust = 1) ) + scale_fill_brewer(type = "qual", palette = "Set1") ``` ## Impact on Intensity Metrics ```{r} # Calculate intensity metrics for both tiers intensity_t1 <- calc_intensity_litre( total_emissions = total_t1, milk_litres = farm_profile$milk_production, fat = 3.7, protein = 3.2 ) intensity_t2 <- calc_intensity_litre( total_emissions = total_t2, milk_litres = farm_profile$milk_production, fat = 3.7, protein = 3.2 ) # Compare intensities intensity_comparison <- data.frame( Metric = c( "Total Emissions (kg CO₂eq)", "Milk Intensity (kg CO₂eq/kg FPCM)", "FPCM Production (kg)", "Difference in Intensity (%)", "Management Classification" ), Tier1 = c( format(round(total_t1$total_co2eq), big.mark = ","), round(intensity_t1$intensity_co2eq_per_kg_fpcm, 3), format(round(intensity_t1$fpcm_production_kg), big.mark = ","), "-", ifelse(intensity_t1$intensity_co2eq_per_kg_fpcm < 1.2, "Good", "Needs Improvement") ), Tier2 = c( format(round(total_t2$total_co2eq), big.mark = ","), round(intensity_t2$intensity_co2eq_per_kg_fpcm, 3), format(round(intensity_t2$fpcm_production_kg), big.mark = ","), round((intensity_t2$intensity_co2eq_per_kg_fpcm - intensity_t1$intensity_co2eq_per_kg_fpcm) / intensity_t1$intensity_co2eq_per_kg_fpcm * 100, 1), ifelse(intensity_t2$intensity_co2eq_per_kg_fpcm < 1.2, "Good", "Needs Improvement") ) ) kable(intensity_comparison, caption = "Intensity Metrics: Tier 1 vs Tier 2") ``` ## Accuracy and Uncertainty ### Uncertainty Ranges by Tier ```{r} uncertainty_analysis <- data.frame( Source = c("Enteric", "Manure", "Soil", "Energy", "Inputs"), Tier1_Uncertainty = c("Higher", "Higher", "Higher", "Lower", "Medium"), Tier2_Uncertainty = c("Medium", "Medium", "Medium", "Lower", "Medium"), Key_Improvement = c( "Diet-specific Ym factors", "VS calculation from intake", "Site-specific soil factors", "No significant change", "Regional emission factors" ) ) kable(uncertainty_analysis, caption = "Uncertainty Comparison by Emission Source") ``` ### Factors Affecting Accuracy ```{r fig.width=10, fig.height=8} # Create accuracy comparison visualization accuracy_data <- data.frame( Factor = c( "Enteric - Default EF", "Enteric - Energy Method", "Manure - Default", "Manure - VS/MCF", "Soil - Standard", "Energy - Standard", "Inputs - Default" ), Tier = c("Tier 1", "Tier 2", "Tier 1", "Tier 2", "Both", "Both", "Both"), Uncertainty_Low = c(70, 85, 60, 75, 50, 85, 75), Uncertainty_High = c(130, 115, 140, 125, 150, 115, 125), Method_Complexity = c(1, 3, 1, 3, 2, 2, 2) ) accuracy_data$Uncertainty_Mid <- (accuracy_data$Uncertainty_Low + accuracy_data$Uncertainty_High) / 2 ggplot(accuracy_data, aes( x = reorder(Factor, Method_Complexity), y = Uncertainty_Mid, color = Tier )) + geom_pointrange(aes(ymin = Uncertainty_Low, ymax = Uncertainty_High), size = 0.8, alpha = 0.8 ) + geom_hline(yintercept = 100, linetype = "dashed", color = "gray50") + coord_flip() + labs( title = "Accuracy Ranges by Methodology and Tier", subtitle = "100 = Perfect accuracy, wider ranges = higher uncertainty", x = "Calculation Method", y = "Accuracy Range (% of true value)", color = "IPCC Tier" ) + theme_minimal() + theme(plot.title = element_text(size = 14, hjust = 0.5)) + scale_color_brewer(type = "qual", palette = "Set1") ``` ## Decision Framework: When to Use Each Tier ### Tier Selection Criteria ```{r} decision_framework <- data.frame( Criterion = c( "Purpose", "Data Availability", "Time Available", "Expertise Level", "Accuracy Needs", "Budget", "Follow-up Actions" ), Use_Tier1 = c( "Regional estimates, screening", "Basic farm records only", "< 1 day", "Basic agricultural knowledge", "Screening-level precision", "Minimal cost", "Awareness, general comparison" ), Use_Tier2 = c( "Farm management, mitigation", "Detailed records + measurements", "2-5 days", "Nutrition/LCA knowledge helpful", "Better precision when detailed inputs are available", "Moderate investment", "Specific interventions, monitoring" ) ) kable(decision_framework, caption = "Tier Selection Decision Framework") ``` ### Cost-Benefit Analysis ```{r} # Cost-benefit comparison cost_benefit <- data.frame( Aspect = c( "Data Collection Cost", "Technical Expertise", "Processing Time", "Result Accuracy", "Management Value", "Policy Applicability" ), Tier1_Score = c(1, 1, 1, 2, 2, 3), # 1=low, 3=high Tier2_Score = c(3, 2, 2, 3, 3, 2), Weight = c(0.2, 0.15, 0.15, 0.25, 0.15, 0.1) # Importance weights ) cost_benefit$Tier1_Weighted <- cost_benefit$Tier1_Score * cost_benefit$Weight cost_benefit$Tier2_Weighted <- cost_benefit$Tier2_Score * cost_benefit$Weight tier1_total <- sum(cost_benefit$Tier1_Weighted) tier2_total <- sum(cost_benefit$Tier2_Weighted) cat("Weighted Decision Scores:\n") cat("Tier 1:", round(tier1_total, 2), "\n") cat("Tier 2:", round(tier2_total, 2), "\n") cat( "\nRecommendation: Use", ifelse(tier2_total > tier1_total, "Tier 2", "Tier 1"), "for most farm-level assessments\n" ) ``` ## Sensitivity Analysis ### Parameter Sensitivity in Tier 2 ```{r} # Test sensitivity of key Tier 2 parameters sensitivity_tests <- list( baseline = list(ym = 6.1, body_weight = 580, dm_intake = 19.2), high_ym = list(ym = 6.8, body_weight = 580, dm_intake = 19.2), low_ym = list(ym = 5.4, body_weight = 580, dm_intake = 19.2), heavy_cows = list(ym = 6.1, body_weight = 650, dm_intake = 19.2), light_cows = list(ym = 6.1, body_weight = 510, dm_intake = 19.2), high_intake = list(ym = 6.1, body_weight = 580, dm_intake = 21.5), low_intake = list(ym = 6.1, body_weight = 580, dm_intake = 16.9) ) sensitivity_results <- lapply(names(sensitivity_tests), function(scenario) { params <- sensitivity_tests[[scenario]] enteric_test <- calc_emissions_enteric( n_animals = farm_profile$dairy_cows, cattle_category = "dairy_cows", avg_milk_yield = farm_profile$milk_yield_per_cow, avg_body_weight = params$body_weight, dry_matter_intake = params$dm_intake, ym_percent = params$ym, tier = 2 ) data.frame( Scenario = scenario, CH4_kg = enteric_test$ch4_kg, CO2eq_kg = enteric_test$co2eq_kg ) }) sensitivity_df <- do.call(rbind, sensitivity_results) %>% mutate( Change_from_baseline = round((CO2eq_kg - CO2eq_kg[Scenario == "baseline"]) / CO2eq_kg[Scenario == "baseline"] * 100, 1) ) kable(sensitivity_df, caption = "Tier 2 Parameter Sensitivity Analysis") ``` ### Impact on Farm Rankings ```{r fig.width=10, fig.height=6} # Create hypothetical farm comparison set.seed(456) farm_comparison <- data.frame( Farm = paste0("Farm_", LETTERS[1:6]), Tier1_Intensity = c(1.15, 1.42, 0.98, 1.65, 1.28, 1.33), Tier2_Intensity = c(1.08, 1.51, 1.12, 1.48, 1.35, 1.29) ) %>% mutate( Tier1_Rank = rank(Tier1_Intensity), Tier2_Rank = rank(Tier2_Intensity), Rank_Change = Tier2_Rank - Tier1_Rank ) # Visualize ranking changes ranking_plot_data <- farm_comparison %>% select(Farm, Tier1_Rank, Tier2_Rank) %>% tidyr::pivot_longer( cols = c(Tier1_Rank, Tier2_Rank), names_to = "Tier", values_to = "Rank" ) %>% mutate(Tier = gsub("_Rank", "", Tier)) ggplot(ranking_plot_data, aes(x = Tier, y = Rank, group = Farm, color = Farm)) + geom_line(size = 1.2, alpha = 0.7) + geom_point(size = 3) + geom_text(aes(label = Farm), vjust = -0.8, size = 3) + scale_y_reverse(breaks = 1:6, labels = paste0("#", 1:6)) + labs( title = "Farm Ranking Changes: Tier 1 vs Tier 2", subtitle = "Lines show how farm rankings change between methodologies", x = "Methodology Tier", y = "Performance Rank (1 = best)" ) + theme_minimal() + theme( legend.position = "none", plot.title = element_text(size = 14, hjust = 0.5) ) kable(farm_comparison[, c("Farm", "Tier1_Intensity", "Tier2_Intensity", "Rank_Change")], caption = "Impact of Methodology on Farm Rankings" ) ``` ## Practical Recommendations ### Implementation Strategy Based on the analysis, here are practical recommendations: #### For Research and Policy - **Use Tier 2** for developing mitigation strategies - **Use Tier 1** for initial screening and regional inventories - **Combine approaches** for cost-effective large-scale assessments #### For Farm Advisors - **Start with Tier 1** to identify high-impact farms - **Upgrade to Tier 2** for detailed improvement plans - **Focus data collection** on parameters with highest uncertainty #### For Farmers - **Tier 1 benefits**: Quick assessment, low cost, baseline establishment - **Tier 2 benefits**: Precise targeting, monitoring progress, optimization ### Quality Assurance ```{r} # Quality control recommendations quality_control <- data.frame( Tier = c("Tier 1", "Tier 1", "Tier 2", "Tier 2", "Both"), Check_Type = c( "Data Range", "Internal Consistency", "Parameter Validation", "Results Plausibility", "Cross-Validation" ), Description = c( "Verify animal numbers and production within expected ranges", "Check milk per cow, stocking rates against system type", "Validate body weights, intakes against literature values", "Compare results with similar farms and published studies", "Run both tiers where possible, investigate large differences" ), Critical_Level = c("Medium", "High", "High", "Medium", "High") ) kable(quality_control, caption = "Quality Assurance Recommendations by Tier") ``` ## Conclusions ### Key Findings 1. **Tier differences**: Tier 2 can differ from Tier 1 because it uses more farm-specific parameters (e.g., intake, body weight, digestibility, Ym). The magnitude and direction of the change depend on the farm system and the quality of the Tier 2 inputs. 2. **Source-specific impacts**: Enteric fermentation and manure management are often the most sensitive to tier choice, because Tier 2 relies on more detailed animal and diet information. 3. **Data investment**: Tier 2 typically requires more detailed data collection and more careful parameter checking, but it can provide results that are more representative of the specific farm when those inputs are reliable. ### Selection Guidelines **Choose Tier 1 when:** - Conducting regional assessments with limited resources - Screening large numbers of farms quickly - Data availability is severely limited - Results are for general awareness or policy screening **Choose Tier 2 when:** - Developing farm-specific mitigation strategies - Monitoring progress over time - Detailed data is available or can be collected - Results will guide significant investments **Use both when:** - Resources allow for comprehensive analysis - Validation of results is critical - Training purposes or methodology development The choice between Tier 1 and Tier 2 should align with the intended use of results, available resources, and required accuracy. cowfootR's flexible implementation of both tiers enables users to select the most appropriate methodology for their specific needs. --- *This analysis demonstrates cowfootR's implementation of IPCC 2019 guidelines. For detailed single-farm analysis, see the "Single Farm Analysis" vignette. For processing multiple farms, consult the "Batch Farm Assessment" vignette.*