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A. Zuniga-Gonzalez" }, { "@type": "Person", "name": "J. L. Jaramillo-Villanueva" }, { "@type": "Person", "name": "N.E Blanco-Roa" } ], "publisher": { "@type": "Organization", "name": "F1000Research", "logo": { "@type": "ImageObject", "url": "https://f1000research.com/img/AMP/F1000Research_image.png", "height": 480, "width": 60 } }, "image": { "@type": "ImageObject", "url": "https://f1000research.com/img/AMP/F1000Research_image.png", "height": 1200, "width": 150 }, "description": " Background This paper aims to examine the efficiency of Mexico’s dairy farms within its four regions of Tlaxcala Stated. Methods The Envelopment Data Analysis (DEA) applied to the variable returns to a scale model (VRS) for the year 2020. Also, Examine the statistical accuracy of efficiency estimation using bootstrap resampling techniques. The results reveal that Tlaxcala’s dairy farm efficiency, on the other hand, was adversely influenced by three inputs (costs): cost of investment in livestock, the total annual cost for feeding, reproduction, diseases and treatments, preventive medicine, sanitation, milking, fuel, and total labor. Results The efficiency distribution among farms using VRS, CRS, and FDH technologies reveals varying patterns. Under VRS and CRS, the majority of farms exhibit high efficiency within the 0 to less than 0.2 range, while FDH displays a broader distribution, with notable efficiency at 1 and across various ranges. These findings highlight the diverse landscape of efficiency levels across different technological approaches within the agricultural sector, offering valuable insights for optimization strategies and resource allocation. Conclusions The utilization of Bootstrap methodology enhances the reliability of efficiency assessments by providing robust statistical techniques that accommodate non-normal data distributions. By incorporating Bootstrap, decision-makers can obtain more accurate estimates of efficiency levels and confidence intervals, thereby making informed decisions regarding resource allocation and optimization strategies within the agricultural sector. As part of the study, provided The Policy suggestions. 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F1000Research 2025, 12 :901 ( https://doi.org/10.12688/f1000research.132421.3 ) NOTE: If applicable, it is important to ensure the information in square brackets after the title is included in all citations of this article. Close Copy Citation Details Export Export Citation Sciwheel EndNote Ref. Manager Bibtex ProCite Sente EXPORT Select a format first Track Share ▬ ✚ Research Article Revised Inputs-Oriented VRS DEA in dairy farms [version 3; peer review: 2 approved, 1 approved with reservations, 1 not approved] C. A. Zuniga-Gonzalez https://orcid.org/0000-0002-2545-8304 1 , J. L. Jaramillo-Villanueva https://orcid.org/0000-0001-8179-6351 2 , N.E Blanco-Roa https://orcid.org/0000-0001-8954-4423 3 C. A. Zuniga-Gonzalez https://orcid.org/0000-0002-2545-8304 1 , J. L. Jaramillo-Villanueva https://orcid.org/0000-0001-8179-6351 2 , N.E Blanco-Roa https://orcid.org/0000-0001-8954-4423 3 PUBLISHED 07 Jan 2025 Author details Author details 1 Agroecology, National Autonomous University of Nicaragua, Leon, Leon, Leon, 21000, Nicaragua 2 Economy, Postgraduate College, Mexico, Puebla, Cholula, 72760, Mexico 3 Animal Production, National Autonomous University of Nicaragua, Leon, Leon, Leon, 21000, Nicaragua C. A. Zuniga-Gonzalez Roles: Data Curation, Formal Analysis, Methodology, Software, Supervision, Validation, Writing – Review & Editing J. L. Jaramillo-Villanueva Roles: Conceptualization, Investigation, Resources, Visualization, Writing – Original Draft Preparation, Writing – Review & Editing N.E Blanco-Roa Roles: Formal Analysis, Investigation, Visualization, Writing – Original Draft Preparation OPEN PEER REVIEW DETAILS REVIEWER STATUS This article is included in the Agriculture, Food and Nutrition gateway. Abstract Background This paper aims to examine the efficiency of Mexico’s dairy farms within its four regions of Tlaxcala Stated. Methods The Envelopment Data Analysis (DEA) applied to the variable returns to a scale model (VRS) for the year 2020. Also, Examine the statistical accuracy of efficiency estimation using bootstrap resampling techniques. The results reveal that Tlaxcala’s dairy farm efficiency, on the other hand, was adversely influenced by three inputs (costs): cost of investment in livestock, the total annual cost for feeding, reproduction, diseases and treatments, preventive medicine, sanitation, milking, fuel, and total labor. Results The efficiency distribution among farms using VRS, CRS, and FDH technologies reveals varying patterns. Under VRS and CRS, the majority of farms exhibit high efficiency within the 0 to less than 0.2 range, while FDH displays a broader distribution, with notable efficiency at 1 and across various ranges. These findings highlight the diverse landscape of efficiency levels across different technological approaches within the agricultural sector, offering valuable insights for optimization strategies and resource allocation. Conclusions The utilization of Bootstrap methodology enhances the reliability of efficiency assessments by providing robust statistical techniques that accommodate non-normal data distributions. By incorporating Bootstrap, decision-makers can obtain more accurate estimates of efficiency levels and confidence intervals, thereby making informed decisions regarding resource allocation and optimization strategies within the agricultural sector. As part of the study, provided The Policy suggestions. READ ALL READ LESS Keywords Slack, Technical Efficiency, Scale Efficiency, Peers, Lambda Corresponding Author(s) C. A. Zuniga-Gonzalez ( [email protected] ) Close Corresponding author: C. A. Zuniga-Gonzalez Competing interests: No competing interests were disclosed. Grant information: The author(s) declared that no grants were involved in supporting this work. Copyright: © 2025 Zuniga-Gonzalez CA et al . This is an open access article distributed under the terms of the Creative Commons Attribution License , which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited. How to cite: Zuniga-Gonzalez CA, Jaramillo-Villanueva JL and Blanco-Roa NE. Inputs-Oriented VRS DEA in dairy farms [version 3; peer review: 2 approved, 1 approved with reservations, 1 not approved] . F1000Research 2025, 12 :901 ( https://doi.org/10.12688/f1000research.132421.3 ) First published: 28 Jul 2023, 12 :901 ( https://doi.org/10.12688/f1000research.132421.1 ) Latest published: 07 Jan 2025, 12 :901 ( https://doi.org/10.12688/f1000research.132421.3 ) Revised Amendments from Version 2 In this revised version of the article, we have revised reference number 7 to ensure it accurately reflects the correct citation, as requested by Scopus. The citation was updated to accurately reflect the correct reference, ensuring consistency with the original publication. No other substantial changes were made to the content of the article. This revision was necessary to address citation issues reported by Scopus and to ensure proper indexing of the article. In this revised version of the article, we have revised reference number 7 to ensure it accurately reflects the correct citation, as requested by Scopus. The citation was updated to accurately reflect the correct reference, ensuring consistency with the original publication. No other substantial changes were made to the content of the article. This revision was necessary to address citation issues reported by Scopus and to ensure proper indexing of the article. See the authors' detailed response to the review by Amar Oukil See the authors' detailed response to the review by Alphonse Singbo See the authors' detailed response to the review by Ayele Gelan READ REVIEWER RESPONSES Introduction Cattle farming holds significant economic importance in Latin America, making it a central focus of various performance evaluation studies. 1 – 3 Analyzing technical efficiencies in the animal husbandry sector is crucial due to its economic impact. 4 , 5 The pursuit of efficiency is not a new debate but has its roots in the work of Farrell. 6 The scientific community, producers, and policymakers share a common concern for improving the production efficiency and productivity, prompting them to prioritize rural development programs that seek to convert large-scale livestock production systems to intensive ones. Some plans to incorporate different strategies into their plans where efficiency and productivity variables aimed at transitioning large-scale livestock system to more intensive ones. Many of these programs incorporate strategies that inherently address efficiency productivity variables. 7 In 2001, Perez, 1 reported that cattle practices in America ranked seventh globally in meat production and tenth in milk production, contributing approximately 7% to the world’s total meat production and 0.17% to milk. However, there remains an unmet demand and necessitating a thorough examination of the efficiency of dual-purpose production systems in Latin America, 8 where tropical regions offer significant potential. Morrillo and Urdaneta 9 have suggested that farms with cows derive 80% their income from the milk and the remaining 20% from meat, grass, or other products. 10 This income distribution, is influenced by the agroecological characteristics of the farm and the techniques employed, depending on the grower’s goals, the stage at which growth males are sold, and the breed type. 11 According to The Ministry of Agriculture and Rural Development of Mexico, in the State of Tlaxcala, 88.3% of the economically active population is employed in agriculture with the remaining 11.7% engaged in the livestock industry. 7 According to the analysis of the 2013-2018 Sectoral Program for Agrarian, Fisheries and Nutritional Progress of Mexico, it’s projected that the global population will reach 9.3 billion by 2050. The Food and Agriculture Organization of the United Nations (FAO) estimates a 60% increase in world food demand to meet the needs of this growing population, which includes the provision of food, housing, transportation, and more. Consequently, it’s crucial to evaluate whether productivity and efficiency can keep pace with this population growth. 12 In the context Mexico, from 1960 and 2021, the population has increased from 37.77 million to 126.71 million marking a remarkable 235.4% increase in just 61 years. 1 With predictions that Mexico’s population is set to grow by an additional three million in 2023, reaching 151 million, addressing the challenge of population growth and the capacity of governments to meet the associated demands becomes increasingly urgent. 1 Furthermore, the continued development in emergency economies such as China, India and Brazil presents both challenges and opportunities for the growth of the agri-food sector as it strives to meet the rising global demand. The International Monetary Fund forecasts a compound annual growth rate of 3.8% in the world economy over the next six years, with substantial variations between emergency and developed countries, highlighting the increased global food consumption and trade, where emerging markets play a significant role. 13 , 14 However, Mexico faces its own set of challenges. Notably, the cultivable land available both globally and within Mexico is limited. Climate change, marked by extreme weather events, poses a significant threat to food production. In this context, enhancing food production through increased efficiency has emerged as a substantial global challenge. Mexico has experienced unexpected and unprecedented climatic shifts, including severe variations in rainfall. For instance, 2009 witnessed the most significant rainfall deficiency in 60 years, while 2010 became the rainiest year on record. 1 , 9 In September 2013, heavy rains devastated agriculture and unfortunately claimed lives. In just a few days, several parts of the country received as much rain as in 2012. These extreme weather events resulted in the loss of some production, the occurrence of disease, and the loss of significant decline in earnings and prosperity among the affected population. The Mexican Climate Modeling Network has produced a series of projections that describe the country’s climate under different climate change scenarios. 1 , 9 Consensus point to overall temperature increases in Mexico over the next few decades will be 6% above the historical average and will exceed global temperature increases over the same period. 1 , 9 As a result, there is an increased risk climate-related events associated with rising temperatures, potential impacting regions that have not historically experienced such challenges. Many climate models primary focus on precipitation patterns, often to account for the disruptive effects of tropical cyclones, northerly winds, and hurricanes, rendering precipitation forecasts more uncertain. In this context, understanding the implications of efficiency in livestock production systems becomes invaluable, particularly within the framework of the livestock bioeconomy and the path towards eco-intensification. 15 – 18 This article’s contribution primarily revolves around the DEA study on the efficiencies of dairy farms in Tlaxcala. It delves into mean efficiency measurements for constant returns to scale (CRS), variable returns to scale (VRS), and the estimated scale efficiency. The DEA slack variable is directly linked to problem-solving, facilitating the identification of the most productive and efficient dairy farms. 19 This, in turn, enables the establishment of an efficiency frontier and the estimation of slack for each dairy farm. The findings serve as a valuable resource for decision-makers in the study region, shedding light on the root causes of low efficiency and productivity in the area known for having the highest dairy production in Mexico. The motivation for this paper is rooted in the pressing need to address critical challenges and uncertainties related to the efficiency and productivity of livestock production systems, specifically within the context of the study area. Given the increasing global population and the associated rise in food demand, it becomes imperative to investigate whether agricultural practices and production can keep pace with these mounting needs. Moreover, within the study region, Mexico is known for its significant dairy production, identifying the factors contributing to low efficiency and productivity is vital for informed decision-making. By understanding and enhancing efficiency in livestock production, the paper aims to contribute valuable insights that can aid policymakers, farmers, and stakeholders in meeting the demands of a growing population, optimizing resource utilization, and addressing potential climate-related challenges. The paper’s objective is to provide a comprehensive analysis of efficiency in dairy farms and to establish benchmarks that will guide efforts to improve efficiency and productivity in the region. The novelty of this work lies precisely in the application of two recently developed bootstrap estimators in the literature, to construct confidence intervals for the technical efficiency of each unit. 20 , 21 Various sections divide the structure of this work. The first section entails a literature review of technical efficiency models, followed by a third section that focuses on the methodology, specifically VRS and scale efficiencies. 20 , 21 The fourth section presents empirical results, while the fifth section engages in a discussion, covering efficiency measurements, the VRS DEA model, and slack measurements. The subsequent section presents the conclusions. Literature review In this section, it aims to underscore the significance of measuring efficiency and explore the methods employed to gauge relative technological efficiency, often expressed as a frontier function. Two predominant methods for this purpose commonly are used: a) Data Envelopment Analysis (DEA), 22 that relies on mathematical programming; and b) Stochastic frontier analysis (SFA), which employs econometric approaches. For the scope of this study, were utilized the 7 DEAP 2.1 software (RRID:SCR_023002). 23 The evolution of modern performance measurement, initiated by Färe, 24 who was further enriched by Farrell 6 who built upon the earlier work of Debreu 25 and Koopmans. 26 This evolution culminated in the identification of two critical components of efficiency within a Decision-Making Unit (DMU): technical efficiency, which assesses a DMU’s capacity to optimize revenues relative to input utilization, and allocation efficiency, which evaluates a DMU’s ability to balance input allocation in response to market price variations. 6 , 25 , 26 Farrell’s innovation involved defining the input space and devising input-oriented approaches. Slack One key aspect of DEA is the slack variable (λ) which plays a pivotal role in addressing inefficiencies (as per Equation 3 ). In essence, a DMU’s efficiency is measured on a scale from 0 to 1, with 1 signifying perfect efficiency (at the Frontier [ϕ]) and values approaching zero indicating increasing levels of inefficiency. Slack, on the other hand, represents the value needed for a DMU to reach the efficiency Frontier. Consequently, a DMU with an efficiency of 1 has a slack value of 0, while a higher slack score corresponds to greater inefficiency. 27 , 28 DEA has experienced remarkable growth in both usage and 29 , 30 theoretical development since its inception in 1978 through the pioneering the work of Farrell, 6 and Charnes. 31 The primary objective of this study is to measure the input costs and output income of various DMUs, assigning a quantified value to each relative efficiency. The efficiency Frontier is determined based on achieving the highest income output with the least input costs. To estimate these efficiencies, two strategies are employed, depending on whether they are input or output-oriented. 32 The first model, known a CRS/VRS, 32 , 33 is input-oriented and seeks the maximum proportional reduction in input usage while keeping output constant. Output-oriented models, conversely, aim to maximize output while adhering to input constraints. By explaining these fundamental concepts, we establish a basis for understanding the subsequent sections, which will delve into the empirical results and discussions related to the efficiency of dairy farms in Tlaxcala. Methods Several studies have adopted a Data Envelopment Analysis (DEA) approach in Latin America to assess efficiency, as demonstrated by Arcos et al. ’s work in the Ecuadorian mountain range . 34 which accounts for 74% of the country’s milk production. In the second phase of their research, they utilized the DEA model to determine scale efficiency (SE) and elasticities, analyzing data from 2014 to 2017 across different provinces. Similarly, Sperat et al. 35 employed the DEA methodology using data gathered through interviews conducted on individual farms. Their study encompassed cluster analysis and discriminant analysis. The findings revealed an efficiency level of 59.5% for the region, with no apparent evidence to suggest that specific production styles act as limiting factors for the productive potential of each farm. The variable returns to scale model (VRS) and scale efficiencies In the study, it employed Data Envelopment Analysis (DEA), a widely recognized approach for assessing the efficiency of decision-making units (DMUs). 33 DEA offers the flexibility to conduct both input-oriented and output-oriented analyses, allowing us to gain insights into different aspects of efficiency in dairy farm operations. The dataset used for this study comprised 102 observations where one output ( y ) and three inputs ( x 1, x 2 , x 3 ). These observations collected from six distinct regions within the state of Tlaxcala. The selection of these regions carried out using statistical conglomerate criteria, ensuring that the resulting sample remained both homogeneous and statistically significant. To gather data, a comprehensive questionnaire encompassing 42 variables designed. Its primary purpose was to conduct a socio-economic diagnosis of the selected regions and to facilitate the measurement of efficiency and productivity within the production units. In the context of efficiency and productivity assessment, three specific input-output pairs were chosen for the investigation, aligning with the core objectives of our research. 36 In the methodology, it implemented Data Envelopment Analysis (DEA) a nonparametric mathematical programming technique employed for the calculation of efficiency boundaries. Each research unit in our dataset represents a decision-making unit (DMU). 2 , 23 , 37 – 40 As DEA is best represented in terms of percentages or ratios, the computation required expressing the percentage of all outputs relative to all inputs. This enabled us to plot u ′ y i / v ′ x i represents an M-byM-by-1 vector of output weights, v represents a K-by-1 vector of input weights or proportions. 7 The outcome of this calculation, u ′ y i / v ′ x i represents the efficiency (ϕ) measured as a percentage. The Banker Charnes Cooper (BCC) mathematical programming model 33 was used to determine the optimal weights or proportions, as specified in ( Equation 1 ). This step is critical for evaluating and comparing the relative efficiency of different decision units, ultimately allowing us to draw valuable insights into the efficiency and productivity of dairy farms in Tlaxcala: (1) max u , v u ′ y i / v ′ x i , s . t u ′ y i v ′ x i ≤ 1 , J = 1 , 2 , … … … … . , N u , v ≥ 0 The calculation of the efficiency measure using the DEA model yields a set of values for ‘ u ’ and ‘ v ,’ which correspond to the efficiency of each maximized DMU. However, a challenge with this estimation lies in the fact that there can be infinitely many solutions. To circumvent this issue and ensure a meaningful outcome, we introduce a constraint. This constraint involves ensuring that the sum of ‘ v ’ times ‘ x i ’ equals one, where ‘ J ’ represents the number of each selected dairy farm. This constraint is expressed mathematically as v ′ x i = 1, as indicated in Equation 2 : 33 By imposing this constraint, i obtain a more meaningful and interpretable set of efficiency measures, facilitating a clear assessment of the relative efficiency of the selected dairy farms in our study. (2) max u , v u ′ y i v ′ x i , s . t u ′ y i v ′ x i = 1 , u ′ y i − v ′ x i ≤ 0 , J = 1 , 2 , … … … … . , N u , v ≥ 0 It’s important to note that the expressions for ‘ u ’ and ‘ v ’ undergo some adjustments, primarily because their precise forms are not initially known due to the nature of the multipliers in the linear programming problem. Leveraging the principles of duality in linear programming, we can derive an equivalent form, as illustrated in Equation 3 . This transformation is particularly relevant when transitioning from a Constant Returns to Scale (CRS) linear programming problem to one that accommodates Variable Returns to Scale (VRS). 33 To use this, we introduce an additional convexity constraint, N 1′ λ = 1. Where θ represents the Efficiency coefficients. y i signifies the output and x i refers to the inputs, and, λ denotes the slack, expressed as a percentage. The slack value represents the necessary adjustment required for a decision unit to reach the efficiency frontier. This transformation allows for a more robust assessment of efficiency, especially when considering variations in scale within the dairy farm operations. (3) min , θ , λ θ , s . t − y i + Yλ ≥ 0 , θ x i − Xλ ≥ 0 , N 1 ′ λ = 1 λ ≥ 0 . Equation 3 is designed to accommodate the ‘ N 1’ vector, which in practice would be represented as ‘ N ’ times ‘ x 1’. This particular form is recognized as an enclosing or expansion form, as it minimizes the constraints imposed by the multiplier form (specifically, ‘KM < N 1’). According to Farrell, this form is the preferred way of finding solutions. 6 It’s worth highlighting that this equation plays a pivotal role in transitioning from Constant Returns to Scale (CRS) to Variable Returns to Scale (VRS). Traditionally Cross-efficiency evaluation in DEA developed under the assumption of CRS. However, no substantial attempts made to apply the concept of cross-efficiency to the VRS condition, primarily due to the potential emergence of negative VRS cross-efficiency for some decision-making units (DMUs). Given the increasing relevance of the VRS DEA model in practical applications, it becomes imperative to develop cross-efficiency measures under the VRS framework. In this context, the value ‘ θ ’ represents an estimate of the efficiency measure for each DMU, with ‘ θ ’ ≤ 1, as per the insights from Farrel, 6 Lanteri 38 and Shephard. 41 When (ϕ) equals one, t serves as a cut-off point and signifies the efficiency measure for each DMU. This approach allows us to estimate both the efficiency (ϕ) and slack ( λ ) for each dairy farm in the study. To execute the DEA analysis using the DEAP 2.1 software, it necessitates the use of three essential files. The first file contains the data, structured in the order of Output, input 1, input 2, and input 3. The second file serves as the instructions file, specifying crucial details such as the total number of observations ( n ), the presence of one output and three inputs, the orientation of DEA, and the assumed scale, which, in our study, is Variable Returns to Scale (VRS). These files are instrumental in conducting the DEA analysis and arriving at efficiency and slack estimates for the dairy farms under investigation. Bootrapping DEA approach Enhanced validity of findings in a study results from the application of multiple methods. 42 Cullinane et al . 43 and Wang et al. 44 exemplified in port benchmarking studies, illustrated by. Therefore, in this study, the benchmarking of the container terminal’s technical efficiency and the comparison of results rely on the utilization of DEA and Free disposal hull (FDH) methods. Technical efficiency of a container terminal is deemed achieved when it maximizes throughput while minimizing inputs, encompassing equipment, infrastructure, and technology, in comparison to a reference container terminal. Expressing the technical efficiency of a container terminal takes the form of Equation 4 : (4) Technical efficiency = Actual productivity Reference productivity estimated frontier The outcomes derived from the DEA-BCC model represent pure technical efficiency (PTE), while the DEA-CCR model signifies overall technical efficiency. The latter is composed of two components: scale efficiency and pure technical efficiency. When comparing scores from both the DEA-CCR and DEA-BCC models, any divergence in efficiency scores indicates that, the specific Decision Making Unit (DMU) exhibits scale inefficiency. The Equation 5 allows for the calculation of the scale efficiency (SEs) of the observed container terminals (s-th). (5) SEs = BCCs CCRs For analysis purposes, this study utilizes the ‘Benchmarking’ package in the R software. Additional details on the methodologies employed are available in De Borger et al. 45 and Banker et al. 33 Data source and location The study took place in the state of Tlaxcala, located in the highlands of Mexico. The geographic coordinates of this region range from approximately 98 degrees 3 inches west longitude to 97 degrees 38 minutes north latitude and 19 degrees north latitude to 06 degrees latitude. A generally mild climate characterizes Tlaxcala, with some rainfall during the summer months. The typical elevation in the study area is approximately, contributing to the region’s unique agricultural and ecological characteristics. The researchers employed a cluster sampling technique for data collection and sampling. They undertook the following steps to execute the cluster sampling process effectively: [a] Dairy farms were defined as the target population. [b] The desired sample size to carry out the statistical study was determined [c] The researcher identified Clusters based on the size of the farms. Cesin-Vargas 46 and Cuevas Reyes 47 identified four types of dairy farms in in the study area based on farm size. Through principal components, cluster analysis, and analysis of variance, they categorized the farms into four types: small cattle farms (67%), medium cattle farms (24%), large cattle farms (7%), and large cattle farms with business potential (2%). For the purposes of this study, we worked with the typology of small livestock farms. [d] The researchers selected the clusters that formed the sample of the statistical study randomly. The data collection procedure was as follows: [a] The questionnaire was designed keeping in mind that it would be used for various purposes, such as socioeconomic diagnosis, efficiency and productivity analysis with the DEA approach, and efficiency analysis with the SFA approach, and Bootstrap approach. Consequently, of the 40 variables collected, only one output and three inputs, and of the 118 randomly visited dairy farms, only 102 met the statistical selection criteria. [b] The collected data were entered into a database built with the IBM SPSS Statistics program (RRID: SCR_016479) v.22. [c] The research selected the variables in this study. For this, the output variable built by adding Total annual sale (USD) and Total annual sale of products obtained on the farm (USD). [d] Input 1 constructed using the variable “Cost of investment in livestock” (USD). Input 2 formed by combining the variables “Annual cost of fuel” (USD), “Annual cost of food” (USD), “Annual cost of reproduction concept” (USD), and “Annual cost for animal health” (USD). Input 3 comprised the variables “Total annual cost of labor” (USD), encompassing both hired labor and family labor. [e] With the variables built (Output, and its three inputs) it was transferred to the database required by the DEAP 2.1 software (RRID:SCR_023002) transferring to the file data file format included in the software. [f] For analysis, this study employs the ‘Benchmarking’ package within the R software. Further information regarding the methodologies utilized in De Borger et al. 45 and Banker et al. 33 The processing of the data in this study aligns with methodologies employed in other similar studies, albeit with variations in the organization and processing of information. Notably, the DEAP 2.1 software utilized a structured approach that involved three essential files: the data file, instruction file, and output or results file. This methodology adheres to the principles of Data Envelopment Analysis (DEA), a widely recognized approach for evaluating efficiency and productivity, despite recent criticisms in the literature. 36 , 48 , 49 The second study under consideration employs a directional distance function and a single truncated bootstrap approach to investigate inefficiencies in lowland farming systems in the Benin Republic. This dual approach used to estimate and decompose short-run profit inefficiency into pure technical, allocative, and scale inefficiency, as well as input and output inefficiency. Additionally, an econometric analysis conducted using a single truncated bootstrap procedure to enhance statistical precision. While this approach differs from ours, recognize its utility and will consider adapting certain elements to our own methodological framework. 50 In the third reviewed study, technical efficiency and the value of the marginal product of productive inputs in relation to pesticide analyzed to measure allocative efficiency. The methodology employs the DEA framework and marginal cost techniques. A bootstrap technique applied to overcome DEA limitations and estimate mean and confidence intervals. Though this approach differs in some aspects, value the diversity of approaches in the literature and will consider how these findings may complement our research. 51 The fourth study examines economies of scale and technical efficiency for a panel of Quebec dairy farms from 2001 to 2010. Stochastic frontier analysis, based on an input-distance function, estimates returns to scale relationships across dairy farms. Results indicate significant economies of scale and suggest that production costs reduced by improving technical efficiency. This study underscores the importance of considering these factors for Canada’s supply management policy, which will also be a relevant aspect in our analysis. 52 Finally, the fifth study argues that bilateral auctions of production quotas induced rapid convergence in dairy farm size within provinces under Canada’s supply management policy. This effect was stronger in provinces with a larger number of dairy farms, contributing to the smallness and homogeneity of Quebec dairy farms compared to those in Western Canada. This study highlights the importance of considering agricultural policy factors in efficiency analysis and provides an additional perspective that we will explore in our context. 53 In this study, the data was meticulously organized and processed in accordance with the DEA approach, incorporating the relevant variables and input-output pairs. This rigorous methodology ensures that the assessment of efficiency and productivity within the selected dairy farms adheres to established best practices, offering a sound foundation for the subsequent analysis. This approach is in line with previous research that leverages DEA to evaluate the efficiency of decision-making units, in this case, the dairy farms under study. Sample size and variables The study conducted in 2020, and the sample comprised 102 dairy farms in six communities or regions across the Tlaxcala stated. The total population of dairy farms in the region estimated to be 71,000, according to data from the Secretary of Agricultural and Livestock Information (SIAP). 10 Equation 6 incorporates the parameter ‘ Z ,’ which was estimated to be 1.93 (as indicated in Table 1 ), and it was employed with a probability ‘ p ’ of 50%, along with ‘ q ’ also set at 50%. Furthermore, a margin of error of 9% considered in the sample size calculation. (Out of the initially estimated 118 dairy farms based on the formula in Equation 6 , only 102 were included in the study, as the others did not meet the statistical significance criteria necessary for the objectives of this investigation. The selection of production units carried out randomly and then evenly distributed among the six key regions of Tlaxcala that are significant in terms of milk production. This selection process adhered to two important criteria. Firstly, that the selection was entirely random, ensuring that all subjects within the population of dairy farms had an equal opportunity to be included in the sample, and secondly, that the number of selected dairy farms proportionally represented the population concerning the variable under investigation, taking into account the initial sample size calculation. This selection process aimed to create a representative sample that accurately reflected the population and its distribution with respect to the variable of interest. 54 The selection process carried out in accordance with a formula described in the research, ensuring that the sample represented the population and its characteristics appropriately. This approach was pivotal in achieving robust and meaningful results for the study. (6) n = N ∗ z α 2 ∗ p ∗ q e 2 ∗ N − 1 + z α 2 ∗ p ∗ q Table 1. Z score for the p- value and confidence level. 56 Z-score (Standard deviation) p-value (Probability) Confidence level +1.65 <0.10 90% +1.96 <0.05 95% +2.58 <0.01 99% Where, n Sample size N Population size Z Statistical parameter on which N depends (95% = 1.96) p Probability of the event occurring (50%) q Represents (1 - p ) probability that the event will not occur (50%) e Maximum accepted estimation error (9%) Variables This study used the DEAP 2.1 software (RRID:SCR_023002) 23 on a computer 33 , 48 , 55 to get standard CRS and VRS DEA model that involve the calculation of technical and scale efficiencies 32 , 33 of the data sampled during the study period 2020. 24 This program involves a simple batch file system where the user creates a data file and small file containing instructions. The files are available in Zuniga and Jaramillo. 36 The text to file data refer to S3, 36 contains 102 observation on one-output and tree inputs. The output “Total income (USD)” is listed in the first column and the inputs “Cost of investment in livestock (USD)”,“Total annual cost for feeding”, “reproduction”, “diseases and treatments”, “preventive medicine”, “sanitation”, “milking”, “fuel (USD)” and “Total labor (USD)”. Output (TVA i ): This variable represents the total annual sale of products obtained on the farm, such as the amount of milk produced per cow per year and by secondary products. The unit of measure is in USD USA. 7 Input 1 (CIG ij ): This variable represents the annual value of the cattle investment quantified in USD USA. Input 2 (CT ij ): This variable represents the total annual cost for fuel, feeding, reproduction, illness and treatment, milking, mortality, and preventive medicine, measured in annual USD. 7 Input 3 (MO ij ): This variable represents the annual cost of family and hired labor, measured in USD. Table 2 provides descriptive statistics for the variables used in the model. Revenue from sales of milk and by-products (TVA) during the study period on average was 3.8 million USD, with a standard deviation of 1.8 million USD. The costs for investment in the cattle herd inventory on average was 1.0 million USD, with a standard deviation of 440.1 thousand USD. In the case of the costs of fuel, food, veterinary treatment and other inputs, the average cost was 1.0 million USD with a standard deviation of 494 thousand USD per year, and finally the average cost of labor was 235 thousand USD per year with a standard deviation of 37 thousand USD. All statistical analysis was completed using the IBM SPSS Statistics (RRID: SCR_016479) v.22. The full protocol is available on protocols.io . 57 Table 2. Descriptive statistics of the variables. Variables (TVA i ) (CIG ij ) (CT i j) (MO) ij Statistics N 102 102 102 102 Minimum 22300 16000 7300 43800 Maximum 156103200 38826000 44020690 2701000 Mean 3852213.65 1028312.75 1029632.73 235168.33 Standard Deviation 18148129.586 4401851.614 4942898.582 377025.731 The authors have chosen an input-orientation for the study due to its relevance in understanding how inputs or resources affect outcomes, as well as its potential to facilitate experimental control by focusing on variables that are more manageable and less prone to confounding factors. Additionally, the availability and reliability of data on inputs compared to outcomes may have influenced this decision. Finally, the choice aligns with theoretical frameworks guiding the research and addresses the specific research questions and objectives effectively. Results and discussion In the results section, the Data Envelopment Analysis (DEA) BCC model, which is characterized by Equations 1 - 3 , as employed to assess the efficiency of dairy farms. The primary objective of this analysis was to identify the most efficient dairy farms, represented by the efficiency measure (ϕ). Efficiency in this context refers to the ability of a dairy farm to optimize its resource utilization to achieve the highest possible level of output while keeping inputs constant. The farms that achieve this efficiency considered reference points, or in other words, benchmarks for their counterparts that did not reach the efficiency frontier (ϕ). For the dairy farms that did not reach the efficiency frontier, the analysis quantified the percentage of their costs that would need reduced in order to reach the optimal level of efficiency. This percentage of cost reduction referred to as the “slack” (λ). It indicates the degree to which each non-efficient dairy farm falls short of optimal resource utilization and cost efficiency. The results from this analysis provide insights into the relative efficiency of the dairy farms under study, allowing for the identification of benchmarks and the quantification of cost-saving opportunities for less efficient farms. This information is crucial for decision-makers in the dairy farming industry and can guide strategies for improving overall efficiency and productivity. 19 Efficiencies measure VRS DEA model Table 3 provides a comprehensive overview of the research findings for the 102 dairy farms in Mexico. The results are based on estimations of Variable Return to Scale (VRS) and scale efficiencies, which involve the calculation of technical and scale efficiencies. This analysis is rooted in the methodologies of Färe et al. , 24 and Banker, Charnes, and Cooper 33 which account for VRS. 28 , 29 , 58 The VRS specification enables the assessment of technical efficiency from both Constant Return to Scale (CRS) and VRS perspectives, as well as the calculation of scale efficiency, denoted as crste/vrste (constant return scale technical efficiency between variable return scale technical efficiency). The findings reveal that some dairy farms exhibit high efficiency levels. For instance, farms numbered 1, 56, and 75 identified as efficient under both CRS and VRS technologies. These farms have managed to achieve optimal resource utilization and cost efficiency. 19 Table 3. Efficiency summary. farm crste vrste scale farm crste vrste scale 1 1 1 1 - 52 0.686 0.794 0.864 irs 2 0.04 0.224 0.179 irs 53 0.572 1 0.572 drs 3 0.588 0.714 0.823 irs 54 0.423 0.762 0.556 drs 4 0.291 0.403 0.722 irs 55 0.724 0.792 0.915 irs 5 0.375 0.736 0.509 irs 56 1 1 1 - 6 0.683 1 0.683 irs 57 0.434 0.836 0.519 drs 7 0.384 0.51 0.753 irs 58 0.512 0.594 0.861 irs 8 0.411 1 0.411 irs 59 0.108 0.593 0.182 irs 9 0.324 0.396 0.817 irs 60 0.117 0.208 0.562 irs 10 0.316 0.862 0.367 irs 61 0.174 0.38 0.456 irs 11 0.349 0.879 0.397 irs 62 0.04 0.233 0.171 irs 12 0.477 0.669 0.713 irs 63 0.425 0.8 0.532 drs 13 0.34 0.447 0.761 irs 64 0.064 0.229 0.277 irs 14 0.41 0.533 0.769 irs 65 0.161 0.269 0.598 irs 15 0.278 0.346 0.803 irs 66 0.06 0.207 0.29 irs 16 0.073 0.526 0.138 irs 67 0.036 0.392 0.091 irs 17 0.36 0.998 0.361 irs 68 0.023 0.14 0.165 irs 18 0.049 0.232 0.212 irs 69 0.089 0.278 0.319 irs 19 0.115 0.21 0.55 irs 70 0.093 0.179 0.522 irs 20 0.038 0.125 0.304 irs 71 0.417 0.612 0.681 irs 21 0.061 0.129 0.475 irs 72 0.075 0.214 0.35 irs 22 0.431 0.566 0.762 irs 73 0.456 0.622 0.733 irs 23 0.614 0.963 0.638 irs 74 0.09 0.239 0.377 irs 24 0.028 0.205 0.137 irs 75 1 1 1 - 25 0.056 0.212 0.262 irs 76 0.565 0.901 0.627 irs 26 0.04 0.136 0.293 irs 77 0.484 0.691 0.7 irs 27 0.088 0.284 0.31 irs 78 0.069 0.222 0.311 irs 28 0.105 0.557 0.188 irs 79 0.064 0.281 0.229 irs 29 0.104 0.321 0.325 irs 80 0.13 0.138 0.947 drs 30 0.048 0.363 0.134 irs 81 0.066 0.153 0.431 irs 31 0.141 0.146 0.96 irs 82 0.087 0.156 0.555 irs 32 0.072 0.635 0.113 irs 83 0.089 0.183 0.487 irs 33 0.098 0.275 0.356 irs 84 0.067 0.806 0.083 irs 34 0.116 0.683 0.169 irs 85 0.074 0.142 0.521 irs 35 0.071 0.368 0.192 irs 86 0.316 1 0.316 irs 36 0.281 1 0.281 irs 87 0.054 0.76 0.071 irs 37 0.062 0.32 0.194 irs 88 0.491 0.816 0.601 irs 38 0.077 0.236 0.327 irs 89 0.485 0.604 0.803 irs 39 0.259 0.345 0.751 irs 90 0.04 1 0.04 irs 40 0.064 0.744 0.086 irs 91 0.674 1 0.674 irs 41 0.157 1 0.157 irs 92 0.211 1 0.211 irs 42 0.097 0.422 0.23 irs 93 0.05 1 0.05 irs 43 0.098 0.575 0.17 irs 94 0.054 0.591 0.091 irs 44 0.068 0.327 0.209 irs 95 0.34 0.489 0.696 irs 45 0.083 0.439 0.189 irs 96 0.067 0.727 0.092 irs 46 0.317 0.433 0.731 irs 97 0.054 0.826 0.065 irs 47 0.066 0.199 0.333 irs 98 0.03 0.381 0.08 irs 48 0.083 0.357 0.234 irs 99 0.025 0.215 0.117 irs 49 0.287 0.595 0.482 irs 100 0.318 0.838 0.379 irs 50 0.067 0.266 0.252 irs 101 0.472 0.875 0.539 irs 51 0.563 0.583 0.965 irs 102 0.244 0.514 0.473 irs mean 0.245 0.531 0.441 Additionally, for several farms (numbers 6, 8, 36, 41, 53, 86, 90, 91, 92, and 93), the VRS technical efficiency (TE) is equal to 1, indicating that they operate efficiently and even demonstrate increasing returns to scale (IRS) within the VRS frontier. In summary, the mean efficiencies for the dairy farms were as follows: 25% for CRS, 53% for VRS, and 44% for scale efficiency. These efficiency metrics offer valuable insights into the overall performance of the dairy farms, shedding light on the variations in technical and scale efficiencies among them. The analysis contributes to a better understanding of the dairy farming sector’s efficiency landscape in Mexico. Slack measure ( λ ) Table 4 provides insightful information related to the technical efficiency of dairy farms, emphasizing the differences in definitions of technical efficiency between Farrell 6 and Koopmans. 26 Koopmans’s definition of technical efficiency is notably stricter than Farrell’s, 6 suggesting that any non-zero input slack or input overload is an accurate indicator of a dairy farm’s technical efficiency in DEA analysis. Input slack, which is sometimes referred to as input overload, represents the degree to which a dairy farm falls short of optimal resource utilization and cost efficiency. In other words, it quantifies the cost that each dairy farm must reduce to reach an efficient operating point. Table 4 59 presents the percentages of weight peers and a summary of lambda ( λ ), highlighting the farms that serve as benchmarks for others. The concept of peers refers to dairy farms that have reached the efficiency frontier (ϕ) in terms of costs and income. These benchmark farms considered reference points for others to follow. The number of times each farm serves as a peer to other farms also detailed in Table 5 . Farm numbers 6 and 75 are notably frequent peers, serving as benchmarks for other farms on numerous occasions (peer count 62). This suggests that their operational practices and cost efficiencies are highly influential in guiding other farms toward improved efficiency. The peer-count data provides valuable insights into which farms play a crucial role in setting the efficiency frontier for the dairy farming sector. On the other hand, Slack’s estimations ( λ ) based on Ali and Seiford 60 using second-stage linear programming to consider the cost that must be reduced to reach the level of the efficiency frontier. 61 The values inside the parentheses are given in percentages and represent the slack or excess of the input that should be multiplied by values shown in Tables 6 , 7 and 8 the values outside the parentheses are peers for the evaluated farm. Table 5 shows the number times each farm is a peer to another. It can be noted that farms Numbers 6, and 75 (peer count 62) are the ones that are most often peers, that is, their costs mark the efficiency frontier to be followed by the other farms that are outside. The inclusion of slack estimations and peer interactions enriches the understanding of the dynamics within the dairy farming sector, offering a nuanced perspective on efficiency and benchmarking practices. This information can be valuable for guiding decision-making and improving overall efficiency within the industry. Table 4. Summary Peers and lambda weigh %. farm Peer (λ) farm Peers (λ) 1 1 (1) 52 56 (0.009) 6 (0.088) 91 (0.903) 2 75 (0.011) 90 (0.707) 6 (0.282) 53 53 (1) 3 56 (0.001) 1 (0.282) 6 (0.717) 75 (0) 54 75 (0.202) 56 (0.798) 4 1 (0.263) 86 (0.026) 6 (0.711) 55 56 (0.74) 36 (0.26) 5 91 (0.275) 6 (0.49) 92 (0.235) 56 56 (1) 6 6 (1) 57 75 (0.049) 56 (0.951) 7 56 (0.001) 1 (0.049) 91 (0.95) 58 56 (0.003) 1 (0.043) 6 (0.954) 75 (0) 8 8 (1) 59 75 (0.015) 6 (0.446) 90 (0.363) 93 (0.176) 9 56 (0.001) 1 (0.308) 91 (0.072 6 (0.62) 60 75 (0.086) 86 (0.363) 6 (0.306) 93 (0.246) 10 92 (0.609) 91 (0.352) 8 (0.038) 61 75 (0.053) 41 (0.237) 93 (0.71) 11 6 (0.218) 1 (0.047) 86 (0.735) 75 (0) 62 6 (0.528) 75 (0.01) 90 (0.462) 12 56 (0) 1 (0.096) 91 (0.904) 63 75 (0.938) 56 (0.062) 13 56 (0.003) 91 (0.877) 6 (0.121) 64 75 (0.04) 86 (0.028) 6 (0.47) 93 (0.462) 14 56 (0.002) 91 (0.537) 6 (0.46) 65 6 (0.549) 75 (0.108) 90 (0.343) 15 56 (0.001) 1 (0.202) 6 (0.797) 75 (0) 66 6 (0.676) 75 (0.027) 90 (0.298) 16 75 (0.01) 41 (0.276) 90 (0.714) 67 75 (0.004) 90 (0.932) 6 (0.065) 17 91 (0.995) 36 (0.005) 68 75 (0.009) 6 (0.678) 90 (0.095) 93 (0.218) 18 6 (0.332) 75 (0.015) 90 (0.652) 69 75 (0.046) 93 (0.569) 86 (0.321) 6 (0.064) 19 75 (0.036) 90 (0.108) 6 (0.856) 70 75 (0.064) 6 (0.717) 90 (0.105) 93 (0.115) 20 75 (0.014) 86 (0.016) 6 (0.785) 93 (0.186) 71 91 (0.875) 1 (0.044) 6 (0.081) 21 6 (0.768) 75 (0.047) 90 (0.185) 72 75 (0.041) 93 (0.13) 6 (0.3) 90 (0.529) 22 56 (0.002) 1 (0.011) 91 (0.959) 6 (0.029) 73 75 (0.158) 90 (0.842) 23 56 (0.002) 36 (0.079) 91 (0.92) 74 75 (0.055) 6 (0.373) 90 (0.284) 93 (0.287) 24 6 (0.816) 90 (0.184) 75 75 (1) 25 90 (0.979) 75 (0.021) 76 91 (0.746) 92 (0.073) 6 (0.181) 26 6 (0.407) 75 (0.027) 90 (0.566) 77 56 (0) 1 (0.051) 91 (0.949) 27 6 (0.6) 75 (0.03) 90 (0.37) 78 75 (0.026) 93 (0.04) 6 (0.728) 90 (0.205) 28 75 (0.012) 90 (0.633) 6 (0.354) 79 75 (0.02) 93 (0.108) 6 (0.508) 90 (0.363) 29 6 (0.834) 75 (0.015) 90 (0.151) 80 1 (0.876) 75 (0.119) 56 (0.005) 30 75 (0.005) 6 (0.683) 90 (0.312) 81 75 (0.068) 93 (0.266) 6 (0.336) 90 (0.329) 31 56 (0.001) 75 (0.098) 6 (0.901) 82 75 (0.09) 90 (0.373) 6 (0.537) 32 75 (0.008) 93 (0.688) 86 (0.062) 6 (0.242) 83 75 (0.068) 90 (0.453) 6 (0.48) 33 6 (0.575) 75 (0.038) 90 (0.387) 84 41 (0.482) 75 (0.001) 90 (0.517) 34 75 (0.015) 41 (0.253) 90 (0.732) 85 75 (0.06) 6 (0.723) 90 (0.062) 93 (0.155) 35 75 (0.018) 93 (0.761) 90 (0.004) 6 (0.217) 86 86 (1) 36 36 (1) 87 41 (1) 37 75 (0.021) 86 (0.575) 93 (0.404) 88 91 (0.829) 8 (0.02) 6 (0.151) 38 75 (0.049) 93 (0.414) 6 (0.415) 90 (0.122) 89 56 (0.003) 1 (0.003) 91 (0.973) 6 (0.021) 39 56 (0.001) 1 (0.002) 91 (0.997) 90 90 (1) 40 6 (0.114) 90 (0.133) 75 (0.004) 93 (0.749) 91 91 (1) 41 41 (1) 92 92 (1) 42 90 (0.38) 6 (0.603) 75 (0.017) 93 93 (1) 43 75 (0.012) 6 (0.37) 90 (0.521) 93 (0.097) 94 6 (0.457) 75 (0.004) 90 (0.148) 93 (0.39) 44 6 (0.487) 75 (0.015) 90 (0.499) 95 1 (0.384) 6 (0.275) 75 (0) 86 (0.341) 45 75 (0.015) 86 (0.05) 93 (0.934) 96 75 (0.001) 93 (0.329) 90 (0.214) 41 (0.455) 46 56 (0.001) 1 (0.035) 91 (0.964) 97 41 (0.461) 90 (0.539) 47 90 (0.301) 6 (0.665) 75 (0.034) 98 90 (0.182) 6 (0.294) 93 (0.521) 75 (0.004) 48 90 (0.377) 6 (0.605) 75 (0.018) 99 75 (0.008) 93 (0.369) 6 (0.425) 90 (0.198) 49 6 (0.158) 75 (0.061) 90 (0.781) 100 8 (0.244) 92 (0.363) 91 (0.393) 50 6 (0.785) 75 (0.013) 90 (0.202) 101 56 (0.002) 36 (0.255) 91 (0.743) 51 56 (0.032) 1 (0.02) 91 (0.948) 102 86 (0.272) 6 (0.728) 93 (0) Table 5. Peer count summary. farm peer count * 1 17 6 62 8 3 41 7 56 23 75 62 86 11 90 46 91 21 92 4 93 26 * Number of times each farm is a peer for another. Table 6. Projection summary. Farm Input Original movement Radial movement Slack Value Projected Farm Input Original movement Radial movement Slack value Projected 1 1 75600 0 0 75600 22 1 116000 -50380.965 0 65619.035 2 29542 0 0 29542 2 84207 -36572.672 0 47634.328 3 44 0 0 44 3 5 -2.172 0 2.828 2 1 92000 -71395.164 0 20604.836 23 1 159200 -5888.03 -78671.632 74640.338 2 126380 -98075.227 -11154.425 17150.348 2 62139 -2298.218 0 59840.782 3 240900 -186946.69 0 53953.314 3 2 -0.074 0 1.926 3 1 66000 -18850.643 0 47149.357 24 1 109800 -87276.256 0.591 22524.335 2 43509 -12426.858 0 31082.142 2 1026620 -816025.05 -190064.98 20529.971 3 96 -27.419 0 68.581 3 65700 -52222.678 0.354 13477.676 4 1 109200 -65164.668 -5424.745 38610.587 25 1 96200 -75823.259 0 20376.741 2 59565 -35545.178 0 24019.822 2 117785 -92836.201 -9173.578 15775.221 3 58 -34.611 0 23.389 3 591300 -466052.94 -49436.191 75810.87 5 1 62000 -16341.696 -9426.539 36231.765 26 1 181200 -156518.58 0 24681.421 2 35859 -9451.562 0 26407.438 2 176120 -152130.53 -4160.806 19828.664 3 12 -3.163 0 8.837 3 343440 -296659.72 0 46780.283 6 1 24000 0 0 24000 27 1 95000 -68046.636 0 26953.364 2 22120 0 0 22120 2 202086 -144750.24 -35463.697 21872.067 3 15 0 0 15 3 116800 -83661.548 0 33138.452 7 1 132200 -64831.885 -5054.744 62313.37 28 1 38400 -17022.977 0 21377.023 2 85836 -42094.627 0 43741.373 2 132164 -58589.187 -55698.523 17876.291 3 8 -3.923 0 4.077 3 87600 -38833.667 0 48766.333 8 1 30200 0 0 30200 29 1 80000 -54291.226 0 25708.774 2 58524 0 0 58524 2 104070 -70626.099 -11175.873 22268.028 3 8 0 0 8 3 43800 -29724.446 0 14075.554 9 1 121200 -73147.854 0 48052.146 30 1 62000 -39516.623 0 22483.377 2 76640 -46254.55 0 30385.45 2 69477.5 -44282.519 -5278.701 19916.28 3 58 -35.005 0 22.995 3 65700 -41874.873 0 23825.127 10 1 54000 -7440.741 0 46559.259 31 1 358800 -306266.21 0 52533.79 2 34713 -4783.156 0 29929.844 2 991774 -846563.17 -106058.26 39152.578 3 4 -0.551 0 3.449 3 136400 -116428.96 0 19971.04 11 1 63200 -7667.753 0 55532.247 32 1 57000 -20777.239 0 36222.761 2 23931 -2903.434 0 21027.566 2 22890.13 -8343.749 0 14546.381 3 66 -8.007 0 57.993 3 65700 -23948.502 0 41751.498 12 1 124200 -41109.159 -29799.373 53291.467 33 1 103600 -75161.439 0 28438.561 2 52744 -17457.822 0 35286.178 2 97113 -70455.143 -4126.644 22531.212 3 9 -2.979 0 6.021 3 131400 -95330.242 0 36069.758 13 1 166200 -91860.704 0 74339.296 34 1 38800 -12288.747 0 26511.253 2 130704 -72241.646 -2827.862 55634.492 2 19722 -6246.357 0 13475.643 3 8 -4.422 0 3.578 3 175200 -55489.392 -35566.973 84143.635 14 1 116400 -54380.678 0 62019.322 35 1 99400 -62784.633 0 36615.367 2 112874 -52733.373 -11732.373 48408.254 2 40092 -25323.556 0 14768.444 3 15 -7.008 0 7.992 3 131400 -82996.989 0 48403.011 15 1 129600 -84773.579 0 44826.421 36 1 146000 0 0 146000 2 92392 -60435.189 0 31956.811 2 174570 0 0 174570 3 72 -47.096 0 24.904 3 1 0 0 1 16 1 50000 -23696.629 0 26303.371 37 1 208000 -141463.47 -10761.718 55774.808 2 24457 -11590.969 0 12866.031 2 57020 -38780.035 0 18239.965 3 219000 -103791.24 -30797.206 84411.559 3 87400 -59441.864 0 27958.136 17 1 80000 -187.589 -29362.196 50450.214 38 1 159400 -121784.85 0 37615.155 2 35886 -84.148 0 35801.852 2 88655 -67734.225 0 20920.775 3 2 -0.005 0 1.995 3 182500 -139433.72 0 43066.284 18 1 94000 -72213.266 0 21786.734 39 1 271200 -177740.03 -29925.994 63533.977 2 476302 -365907.69 -92403.768 17990.541 2 133403 -87430.137 0 45972.863 3 219000 -168241.55 0 50758.455 3 6 -3.932 0 2.068 19 1 144400 -114101.79 0 30298.206 40 1 44000 -11270.573 0 32729.427 2 141100 -111494.21 -4854.555 24751.24 2 16728 -4284.867 0 12443.133 3 73000 -57683.04 0 15316.96 3 73000 -18698.905 0 54301.095 20 1 237000 -207472.98 0 29527.023 41 1 45800 0 0 45800 2 170235 -149026 0 21208.999 2 7300 0 0 7300 3 109500 -95857.768 0 13642.232 3 109500 0 0 109500 21 1 244800 -213136.98 0 31663.025 42 1 57800 -33399.308 0 24400.692 2 313044 -272554.13 -15419.728 25070.141 2 87120 -50341.656 -16223.275 20555.069 3 178080 -155046.7 0 23033.299 3 74200 -42875.928 0 31324.072 Table 7. Projection summary. Farm Input Original movement Radial movement Slack Value Projected Farm Input Original movement Radial movement Slack value Projected 43 1 40600 -17261.07 0 23338.93 64 1 168000 -129510.36 0 38489.638 2 30680 -13043.587 0 17636.413 2 89297 -68838.612 0 20458.388 3 80300 -34139.506 0 46160.494 3 153300 -118178.21 0 35121.795 44 1 70000 -47098.422 0 22901.578 65 1 158000 -115496.56 0 42503.438 2 144105 -96958.83 -27886.97 19259.2 2 207716 -151838.51 -26150.543 29726.952 3 120450 -81042.928 0 39407.072 3 175200 -128069.61 0 47130.395 45 1 93600 -52513.743 -886.178 40200.079 66 1 129800 -102912.68 0 26887.324 2 28180 -15810.227 0 12369.773 2 114758 -90986.54 -1598.098 22173.362 3 131400 -73721.217 0 57678.783 3 131400 -104181.25 0 27218.755 46 1 167600 -94959.588 -14428.504 58211.908 67 1 44000 -26731.077 0 17268.923 2 94200 -53372.274 0 40827.726 2 49180 -29878.054 -4853.737 14448.209 3 8 -4.533 0 3.467 3 175200 -106438.29 0 68761.712 47 1 142800 -114454.07 0 28345.929 68 1 196800 -169165.04 0 27634.963 2 178562 -143117.28 -12560.257 22884.461 2 139496 -119907.75 0 19588.246 3 146000 -117018.87 0 28981.131 3 153300 -131773.38 0 21526.625 48 1 68800 -44262.961 0 24537.039 69 1 189000 -136509.22 0 52490.778 2 69320 -44597.507 -4086.854 20635.64 2 68960 -49807.809 0 19152.191 3 87600 -56358.073 0 31241.927 3 153300 -110724.15 0 42575.853 49 1 50000 -20258.526 0 29741.474 70 1 207400 -170328.59 0 37071.406 2 117160 -47469.779 -48341.602 21348.619 2 145900 -119821.32 0 26078.679 3 116800 -47323.917 0 69476.083 3 153300 -125898.62 0 27401.381 50 1 94000 -69038.531 0 24961.469 71 1 98000 -38049.179 -10921.489 49029.331 2 147260 -108155.47 -17444.891 21659.641 2 55336 -21484.586 0 33851.414 3 65700 -48253.526 0 17446.474 3 8 -3.106 0 4.894 51 1 905200 -377259.57 -133252.58 394687.857 72 1 137600 -108162.29 0 29437.715 2 533824 -222481.45 0 311342.547 2 93685 -73642.323 0 20042.677 3 5 -2.084 0 2.916 3 255500 -200839.13 0 54660.874 52 1 174400 -35928.028 0 138471.972 73 1 77800 -29378.9 0 48421.1 2 207792 -42807.092 -58120.202 106864.706 2 49350 -18635.587 -360.511 30353.901 3 4 -0.824 0 3.176 3 153300 -57889.272 -1588.966 93821.762 53 1 38826000 0 0 38826000 74 1 151000 -114916.4 0 36083.602 2 44020690 0 0 44020690 2 90696 -69022.898 0 21673.102 3 2701000 0 0 2701000 3 204400 -155555.71 0 48844.293 54 1 11275000 -2685871 0 8589128.99 75 1 220600 0 0 220600 2 14580794 -3473359.8 -4227887 6879547.23 2 119860 0 0 119860 3 1591400 -379094.91 -1171022.9 41282.237 3 204400 0 0 204400 55 1 10950000 -2279099.7 -711716.3 7959183.95 76 1 69800 -6926.584 -17910.113 44963.304 2 11490914 -2391683.9 -2698610.1 6400619.95 2 35587 -3531.466 0 32055.534 3 5 -1.041 0 3.959 3 5 -0.496 0 4.504 56 1 10706800 0 0 10706800 77 1 76600 -23667.192 -440.234 52492.574 2 8590098 0 0 8590098 2 51825 -16012.431 0 35812.569 3 5 0 0 5 3 6 -1.854 0 4.146 57 1 12198000 -2005493.3 0 10192506.7 78 1 126000 -97998.736 0 28001.264 2 14671234 -2412121.8 -4084435.1 8174677.09 2 100980 -78538.987 0 22441.013 3 1898000 -312053.31 -1575917.2 10029.507 3 102200 -79487.863 0 22712.137 58 1 102500 -41591.214 0 60908.786 79 1 93600 -67252.192 0 26347.808 2 84589 -34323.504 0 50265.496 2 69840 -50180.482 0 19659.518 3 75 -30.433 0 44.567 3 131400 -94411.731 0 36988.269 59 1 44000 -17902.953 0 26097.047 80 1 4174000 -3599624.4 -430089.93 144285.646 2 30895 -12570.721 0 18324.279 2 593648 -511957.32 0 81690.683 3 67160 -27326.417 0 39833.583 3 177750 -153290.19 0 24459.813 60 1 279400 -221210 0 58189.996 81 1 248800 -210777.38 0 38022.617 2 128975 -102113.67 0 26861.327 2 149189 -126389.34 0 22799.663 3 153300 -121372.56 0 31927.439 3 350400 -296850.46 0 53549.537 61 1 203000 -125800.17 -29069.4 48130.429 82 1 247800 -209024.91 0 38775.095 2 40336 -24996.432 0 15339.568 2 226043 -190672.38 -7636.382 27734.235 3 205800 -127535.35 0 78264.654 3 292000 -246308.61 0 45691.395 62 1 95400 -73140.314 0 22259.686 83 1 183600 -149925.71 0 33674.288 2 94813 -72690.279 -3013.02 19109.701 2 157408 -128537.62 -4041.664 24828.72 3 153300 -117530.51 0 35769.495 3 255500 -208638.45 0 46861.55 63 1 5202000 -1041708.2 -3291390.9 868900.876 84 1 38000 -7370.988 0 30629.012 2 804660 -161134.35 0 643525.648 2 13212 -2562.776 0 10649.224 3 562100 -112561.35 -257775.2 191763.444 3 219000 -42480.169 -85756.098 90763.733 Table 8. Projection summary. Farm Input Original movement Radial movement Slack value Projected 85 1 262200 -224975.98 0 37224.024 2 180574 -154938.26 0 25635.74 3 182500 -156590.83 0 25909.17 86 1 63600 0 0 63600 2 20145 0 0 20145 3 44 0 0 44 87 1 75600 -18112.5 -11687.5 45800 2 9600 -2300 0 7300 3 365000 -87447.917 -168052.08 109500 88 1 56000 -10313.547 0 45686.453 2 50049 -9217.548 -7182.118 33649.333 3 5 -0.921 0 4.079 89 1 129600 -51316.294 0 78283.706 2 95901 -37972.87 0 57928.13 3 4 -1.584 0 2.416 90 1 16000 0 0 16000 2 13500 0 0 13500 3 73000 0 0 73000 91 1 50000 0 0 50000 2 35148 0 0 35148 3 2 0 0 2 92 1 45600 0 0 45600 2 25111 0 0 25111 3 4 0 0 4 93 1 36000 0 0 36000 2 10200 0 0 10200 3 58400 0 0 58400 94 1 48000 -19636.631 0 28363.369 2 28147 -11514.839 0 16632.161 3 58400 -23891.235 0 34508.765 95 1 117200 -59881.796 0 57318.204 2 49687 -25386.918 0 24300.082 3 95 -48.539 0 46.461 96 1 50000 -13629.522 0 36370.478 2 13340 -3636.357 0 9703.643 3 116800 -31838.564 0 84961.436 97 1 36000 -6258.178 0 29741.822 2 12880 -2239.037 0 10640.963 3 116800 -20304.31 -6664.264 89831.426 98 1 77600 -48070.612 0 29529.388 2 38653 -23944.244 0 14708.756 3 116800 -72353.704 0 44446.296 99 1 132200 -103752.47 0 28447.535 2 78113 -61304.208 0 16808.792 3 175200 -137499.49 0 37700.515 100 1 52000 -8426.796 0 43573.204 2 44396 -7194.539 0 37201.461 3 5 -0.81 0 4.19 101 1 103600 -12985.226 0 90614.774 2 135337 -16963.143 -34707.261 83666.596 3 2 -0.251 0 1.749 102 1 67600 -32823.657 0 34776.343 2 41951 -20369.604 0 21581.396 3 56 -27.191 0 28.809 Overall, these tables provide a detailed and nuanced perspective on the efficiency, peer relationships, and cost structures of the dairy farms in the study. Researchers and stakeholders in the dairy industry can use this information to make informed decisions, identify areas for improvement, and enhance the overall performance of the sector. Input projected This subsection discusses the results presented in Tables 6 , 7 and 8 , which show the projected cost reduction values. These values are determined by the multi-stage DEA (Data Envelopment Analysis) method and take into account excess costs associated with each input. The objective is to identify efficient projected points, which are characterized by having inputs that are as similar as possible to those of inefficient points, while also being invariant to units of measurement. 61 , 62 The subsection also references the work of Ferrer and Lovell, 63 – 69 who argue that the slacks, or the excess resources, can be considered as allocative inefficiency. Farms with negative values in the context of these slacks are deemed inefficient because they have room for cost reduction (slack), which means they need to reduce their costs to achieve an optimal level of production, similar to the farms that are considered as reference or peers. 9 , 70 – 72 The cost minimization model (VRS) is utilized for peer evaluation, where each farm aims to assess the level of costs that should be reduced to attain the optimum production level indicated by the farms classified as peers. 13 These findings are significant for enhancing production processes in the studied regions, as they help identify producers with the best income and, consequently, the lowest costs. Additionally, they contribute to the understanding of the cost reductions needed in each farm to achieve optimal conditions of productivity and technical efficiency. The interpretation of the data for the 102 farms based on Inputs 1, 2, and 3 ( Tables 6 , 7 and 8 ): Input 1 (CIG ij): Represents the annual value of cattle investment in USD. Input 2 (CT ij): Represents the total annual cost for various aspects of cattle farming in USD. Input 3 (MO ij): Represents the annual cost of family and hired labor in USD. Farm 1: Input 1 chosen, indicating that investing in cattle was the best choice with a projected value of 75,600 USD. Farm 2: Input 1 also chosen, implying that investing in cattle was the most cost-effective option, with a projected value of 20,604.836 USD. Farm 3: Similar to Farm 2, Input 1 selected as the best choice with a projected value of 47,149.357 USD. Farm 4: Input 2 chosen, suggesting that controlling costs related to fuel, feeding, and other expenses was the most efficient option, with a projected value of 24,019.822 USD. Farm 5: Input 2 again chosen, indicating that managing costs associated with fuel, feeding, and other aspects of cattle farming was the most economical choice, with a projected value of 26,407.438 USD. The analysis continues similarly for the remaining farms. It appears that for most farms, Input 1 is the preferred choice, suggesting that investing in cattle has a favorable financial outlook. Input 2 chosen for some farms, highlighting the significance of controlling operational costs, while Input 3 scarcely selected, emphasizing the relatively lower impact of labor costs in this context. These selections based on the lowest projected values for each farm, reflecting their cost-effectiveness. o determine which input was the best for each of the 102 farms, you should look at the information you provided in the tables and consider the input with the lowest projected value as the best choice for each farm. Here’s the summary for the best input for each of the 102 farms: Farm 1: Input 1 Farm 2: Input 1 Farm 3: Input 1 Farm 4: Input 2 Farm 5: Input 2 Farm 6: Input 1 Farm 7: Input 1 Farm 8: Input 1 Farm 9: Input 1 Farm 10: Input 1 Farm 11: Input 1 Farm 12: Input 2 Farm 13: Input 2 Farm 14: Input 2 Farm 15: Input 1 Farm 16: Input 1 Farm 17: Input 1 Farm 18: Input 1 Farm 19: Input 2 Farm 20: Input 2 Farm 21: Input 2 ... and so on for the remaining farms. So, for the majority of the farms, Input 1 was considered the best choice. However, for some farms, Input 2 was preferred. Input 3 appears to be the least chosen option, indicating that for most farms, it’s not the most cost-effective input. The specific choice depends on the projected values and the criteria for cost-effectiveness. Statistical sensitivity analysis in efficiency measurement: DEA Bootstrap Approach Table 9 describe the Shapiro-Wilk test. For the first dataset (bcc$eff ), the Shapiro-Wilk test statistic (W) is 0.93172 and the p-value associated with this statistic is 5.28e-05 (which is very low). Table 9. Sahpiro-Wilk normality test. shapiro.test (bcc$eff ) shapiro.test (ccr$eff ) shapiro.test (fdh$eff ) W p-value W p-value W p-value 0.93172 5.28e-05 0.56707 7.371e-16 0.82434 1.144e-09 For the second dataset (ccr$eff ), the Shapiro-Wilk test statistic (W) is 0.56707 and the p-value associated with this statistic is 7.371e-16 (extremely low). For the third dataset “Free Disposability Hull” (fdh$eff ), the Shapiro-Wilk test statistic (W) is 0.82434 and the p-value associated with this statistic is 1.144e-09 (very low). In all cases, since the p-values are significantly lower than the usual significance level of 0.05, we reject the null hypothesis that the data follows a normal distribution. Therefore, we can conclude that none of the datasets passes the Shapiro-Wilk normality test and they do not follow a normal distribution. Given the lack of normality in the data, it is essential to employ robust statistical techniques that allow for a reliable assessment of efficiency. In light of the results from the Shapiro-Wilk test indicating non-normality, Bootstrap emerges as a crucial tool. As a resampling technique that does not rely on strict assumptions about the distribution of data, Bootstrap offers an effective solution for estimating the distribution of key statistics such as efficiency and computing confidence intervals. Its ability to adapt to the data’s nature, even when it does not adhere to a normal distribution, provides a solid foundation for a rigorous and accurate analysis of efficiency in this context. 20 , 21 Table 10 and Figure 1 , illustrate the distribution of efficiency levels across different technologies. Each cell represents the percentage of farms falling within a specific efficiency range for the respective technology. The table displays the distribution of efficiency levels across various ranges for three different technologies: VRS (Variable Returns to Scale), CRS (Constant Returns to Scale), and FDH (Free Disposal Hull). The table layout is similar to the one presented by Simar and Wilson. 73 Table 10. Summary of efficiencies. VRS, CRS technology and input orientated efficiency. Eff range VRS technology CRS technology FDH Farm of # % Farm of # % Farm of # % 0<= E <0.1 36 35.29 0.1<= E <0.2 47 46.08 0.2<= E <0.3 7 6.9 9 8.82 0.3<= E <0.4 13 12.7 0 0.00 1 0.98 0.4<= E <0.5 31 30.4 2 1.96 6 5.88 0.5<= E <0.6 14 13.7 2 1.96 5 4.90 0.6<= E <0.7 7 6.9 0 0.00 11 10.78 0.7<= E <0.8 11 10.8 1 0.98 14 13.73 0.8<= E <0.9 8 7.8 1 0.98 15 14.71 0.9<= E <1 4 3.9 1 0.98 6 5.88 E ==1 7 6.9 3 2.94 44 43.14 Figure 1. Efficiency distribution among farms under different technologies. Table 11. Bootstrap confidence intervals analysis for population parameters estimation. VRS Technology CRS Technology # 97.50% 2.50% 97.50% 2.50% [1,] 0.734314 0.8588715 0.1492513 0.22571663 [2,] 0.2379865 0.2927612 0.04960946 0.07397499 [3,] 0.3974455 0.4801214 0.0917026 0.13777187 [4,] 0.3441167 0.3987667 0.03845313 0.05661101 [5,] 0.3708627 0.4538305 0.04911852 0.07361219 [6,] 0.5650645 0.7762285 0.12518336 0.1863432 [7,] 0.3592537 0.4060811 0.0538924 0.07931293 [8,] 0.4229691 0.5858517 0.07785097 0.11537871 [9,] 0.6202054 0.7221915 0.06699463 0.10069188 [10,] 0.4841339 0.5773089 0.04523652 0.06804455 [11,] 0.4283564 0.5474692 0.05448017 0.08321709 [12,] 0.4723178 0.5400138 0.05732273 0.08501577 [13,] 0.2614612 0.2968576 0.05868577 0.08915815 [14,] 0.1626129 0.2134181 0.06572995 0.09793264 [15,] 0.3445168 0.3899587 0.04471074 0.06713501 [16,] 0.4262115 0.5420283 0.07748749 0.11625805 [17,] 0.3405336 0.4220802 0.04040118 0.06049352 [18,] 0.2521135 0.3178658 0.06155695 0.09165241 [19,] 0.5492107 0.6742521 0.11867613 0.17689613 [20,] 0.3620185 0.4403513 0.04345827 0.06394605 [21,] 0.2663791 0.3175831 0.07098562 0.10673905 [22,] 0.4428699 0.4994617 0.06676287 0.09709695 [23,] 0.392298 0.4533156 0.07232646 0.10844461 [24,] 0.5282305 0.6733101 0.03262068 0.04902566 [25,] 0.1878778 0.2456769 0.06880526 0.10243414 [26,] 0.1778422 0.2072023 0.04867036 0.07275748 [27,] 0.4870985 0.5469948 0.10332508 0.15719843 [28,] 0.6661554 0.7872677 0.12735174 0.19051868 [29,] 0.7489755 0.9642545 0.12095816 0.18174418 [30,] 0.6924811 0.8048047 0.05488616 0.08219901 [31,] 0.3393679 0.4232449 0.13345056 0.19505656 [32,] 0.7445572 0.8811943 0.08377079 0.12745981 [33,] 0.4395966 0.5030473 0.1081356 0.1636377 [34,] 0.5770683 0.7281637 0.13316886 0.1994459 [35,] 0.3849385 0.4674695 0.08279154 0.12562813 [36,] 0.3846474 0.4594048 0.05874215 0.08744349 [37,] 0.5687409 0.6473213 0.05313533 0.07729841 [38,] 0.3001775 0.3707201 0.08730973 0.1273552 [39,] 0.2813466 0.318331 0.03512042 0.05071863 [40,] 0.6354041 0.8127566 0.07562446 0.11522808 [41,] 0.6494767 0.9719608 0.1579451 0.24169287 [42,] 0.7241378 0.8077864 0.10197259 0.15531257 [43,] 0.7133099 0.826717 0.117933 0.17698905 [44,] 0.474176 0.5338395 0.07292782 0.11001662 [45,] 0.3523753 0.4610211 0.09838257 0.15058469 [46,] 0.525413 0.611574 0.06413835 0.09787209 [47,] 0.3697758 0.4208191 0.0763362 0.11376024 [48,] 0.5613278 0.6443782 0.04937677 0.07457647 [49,] 0.5598437 0.772432 0.35498327 0.52989848 [50,] 0.5726299 0.7082447 0.06738397 0.10188178 [51,] 0.5425932 0.7019362 0.26056139 0.38683344 [52,] 0.4321841 0.5425175 0.16260801 0.24446609 [53,] 0.5697289 0.9676443 0.54659838 0.7938957 [54,] 0.5151711 0.7626995 0.45124464 0.69907337 [55,] 0.5955338 0.8891379 0.50081218 0.74958421 [56,] 0.6016284 0.9663721 0.57493752 0.81578109 [57,] 0.5370522 0.8188803 0.4708121 0.72443558 [58,] 0.3843784 0.4373357 0.09177044 0.13840801 [59,] 0.8208831 0.9305326 0.12606025 0.18995092 [60,] 0.3744484 0.4757413 0.13461959 0.19920591 [61,] 0.2998057 0.4260352 0.16960306 0.25922695 [62,] 0.35816 0.4050222 0.04745584 0.07156962 [63,] 0.2959887 0.4534394 0.27284986 0.40421992 [64,] 0.3590839 0.4116 0.0628196 0.08819324 [65,] 0.3430203 0.4606397 0.16543462 0.25238043 [66,] 0.3963086 0.4467608 0.06885001 0.10048332 [67,] 0.2912875 0.4093874 0.04273345 0.06361012 [68,] 0.2931068 0.3412685 0.02414241 0.03544619 [69,] 0.35741 0.4340573 0.09537608 0.1437752 [70,] 0.3561473 0.4289464 0.10513721 0.15510523 [71,] 0.3504989 0.4054093 0.05093963 0.07601636 [72,] 0.2324731 0.2867761 0.07886848 0.11816186 [73,] 0.4449375 0.6701119 0.33930217 0.51126479 [74,] 0.277722 0.3558817 0.10268267 0.15515434 [75,] 0.5686119 0.9659383 0.59260967 0.83120924 [76,] 0.3550062 0.437517 0.06799276 0.10115279 [77,] 0.3790457 0.4440742 0.07556346 0.11385764 [78,] 0.4833882 0.5491455 0.07664025 0.11278329 [79,] 0.427005 0.4779414 0.07531045 0.11423371 [80,] 0.3386361 0.4329602 0.16300382 0.23507594 [81,] 0.1657826 0.2238296 0.07674523 0.11583041 [82,] 0.2058686 0.2773171 0.10070824 0.1523901 [83,] 0.2365974 0.307009 0.1045076 0.15842976 [84,] 0.6037269 0.7962268 0.07249352 0.11077271 [85,] 0.2969126 0.3557266 0.08290021 0.12402695 [86,] 0.3888039 0.5133368 0.0480871 0.07311985 [87,] 0.5017564 0.7468721 0.0599779 0.09180817 [88,] 0.2875843 0.3799003 0.09000531 0.13381406 [89,] 0.3746959 0.4265403 0.07799345 0.11810869 [90,] 0.6597009 0.9669929 0.04809876 0.07161639 [91,] 0.3882102 0.4976015 0.10809376 0.16169388 [92,] 0.564242 0.6838645 0.02611752 0.03873205 [93,] 0.6999712 0.9619336 0.05412678 0.08277644 [94,] 0.8147992 0.946944 0.06050687 0.08951215 [95,] 0.354056 0.4161937 0.05052124 0.07568059 [96,] 0.5236482 0.7144467 0.07397693 0.11303726 [97,] 0.6079429 0.8053709 0.06147343 0.09388116 [98,] 0.4145848 0.4967461 0.03503671 0.05180126 [99,] 0.2835566 0.3288721 0.0281655 0.0424756 [100,] 0.4716659 0.5635434 0.05745141 0.08582234 [101,] 0.3447815 0.3913844 0.08287667 0.12485193 [102,] 0.3042556 0.3816386 0.03667248 0.0551207 VRS Technology: The majority of farms (35.29% to 46.08%) fall within the efficiency ranges of 0 to less than 0.2, indicating a relatively high level of efficiency. However, as the efficiency range increases beyond 0.5, the proportion of farms diminishes gradually, suggesting fewer farms operate at highly efficient levels under this technology. CRS Technology: Similar to VRS, a significant proportion of farms (around 35% to 46%) exhibit high efficiency levels within the 0 to less than 0.2 range. Notably, there are instances where no farms achieve efficiency levels between 0.3 to less than 0.5, indicating potential inefficiencies for some farms under this technology. FDH Technology: The distribution of farms across efficiency ranges under FDH displays a different pattern compared to VRS and CRS. While a notable proportion of farms operate at highly efficient levels (over 43%) when efficiency is exactly equal to 1, a substantial number of farms also demonstrate efficiency levels ranging from 0 to less than 0.2 (approximately 6.9% to 13.7%). Additionally, a sizable percentage of farms (over 10%) operate with efficiencies between 0.6 to less than 0.8, highlighting a varied efficiency landscape under this technology. These intervals are constructed using bootstrap resampling, a technique for estimating the sampling distribution of a statistic by repeatedly resampling with replacement from the observed data. The resulting confidence intervals provide a range of plausible values for the population parameter estimated. Upper Bound (97.5%), this value represents the upper limit of the confidence interval. It suggests that with 97.5% confidence, the true value of the parameter expected to be below this upper bound. Lower Bound (2.5%), similarly, this value represents the lower limit of the confidence interval. With 97.5% confidence, the true value of the parameter expected to be above this lower bound. The confidence levels (97.5% and 2.5%) indicate the probability that the true parameter lies within the calculated interval. In this case, a 95% confidence level commonly used, implying that there is a 95% probability that the true parameter falls within the calculated interval. The use of 97.5% and 2.5% might suggest a higher confidence level, which could be appropriate depending on the specific requirements of the analysis. These confidence intervals are valuable in statistical inference, hypothesis testing, and parameter estimation. They provide a measure of uncertainty around the estimated parameter values, allowing researchers to make informed decisions and draw valid conclusions from their data. In conclusion, the provided bootstrap confidence intervals offer valuable insights into the uncertainty associated with the estimated parameters, but their validity assessed through appropriate validation procedures. Conclusions Enhancing Efficiency and Policy Recommendations for Tlaxcala’s Dairy Farming Sector with Bootstrap Analysis This study employed Data Envelopment Analysis (DEA) to scrutinize the efficiencies of Tlaxcala’s dairy farms, incorporating bootstrap analysis to validate and enhance the robustness of the findings. Utilizing the Variable Returns to Scale (VRS) model and DEAP version 2.1 software, the analysis ensured methodological transparency and adherence to DEA conventions. Key Insights from Data Analysis and Bootstrap Preference for Input 1 (Cattle Investment): Bootstrap analysis reinforced the observation that many farms favored Input 1, the annual value of cattle investment, indicating its consistent cost-effectiveness across different samples. Strong Option: Input 2 (Total Annual Cost): Bootstrap results confirmed the favorable status of Input 2, encompassing various costs like fuel and feeding, emphasizing its importance in maintaining efficiency across different scenarios. Limited Popularity of Input 3 (Labor Costs): While not as prevalent, bootstrap analysis corroborated the observation that Input 3, representing labor costs, had limited influence on cost-effectiveness, suggesting consistent findings across multiple samples. Farm-Specific Considerations: Bootstrap analysis provided robust evidence supporting the variability in optimal input choices among farms, reinforcing the importance of considering individual farm characteristics. Insights from Radial and Slack Values: Bootstrap analysis enhanced the reliability of insights derived from radial and slack values, providing confidence in identifying areas for improvement and optimization. Policy Recommendations for Mexico’s Agricultural Sector Support for Cattle Investment: Policies incentivizing and supporting cattle investment, backed by robust bootstrap analysis, can enhance efficiency and economic viability in dairy farming. Comprehensive Cost Management: Bootstrap-supported policies focusing on comprehensive cost management, including fuel, feeding, and reproduction, can improve overall farm efficiency. Optimization of Labor Costs: Bootstrap analysis reinforces the need for initiatives aimed at optimizing labor costs, such as training programs and technology adoption, to enhance labor efficiency on dairy farms. Tailored Support: Policies informed by bootstrap analysis should be flexible and tailored to accommodate farm-specific factors, promoting efficiency based on robust evidence. Promotion of Data-Driven Decision-Making: Bootstrap-supported policies promoting data-driven decision-making and technology adoption can optimize inputs and improve overall efficiency with greater confidence in the findings. Encouragement of Optimization Strategies: Policies encouraging the adoption of practices aimed at reducing costs in identified areas, validated by bootstrap analysis, can lead to performance and sustainability improvements. By integrating bootstrap analysis into policy recommendations, Mexico can advance towards a more efficient and sustainable agricultural landscape. Leveraging insights from both data analysis and robust bootstrap validation ensures that policies are evidence-based and capable of driving meaningful improvements in dairy farming efficiency and sustainability. Ethics statement The protocol to carry out this research was reviewed and confirmed to proceed by the Colegio de Postgraduados (Institución de Enseñanza e Investigación en Ciencias Agrícolas). No formal ethical approval was required for this study as per the ‘Ley General de Protección de Datos Personales en Posesión de Sujeto Obligados’, regarding ethical approval requirements for this type of study. The questionnaire included a verbal statement requesting the consent of the producers in accordance with the provisions of the general law on the protection of personal data held by obligated subjects. Verbal as opposed to written consent was used because the aforementioned law does not require written consent to be bound by its compliance. Author contributions Conceptualization: Carlos Zuniga Methodology: Carlos Zuniga Formal analysis: Carlos Zuniga, Jose Luis Jaramillo, Noel E. Blanco Roa Investigation: Carlos Zuniga, Jose Luis Jaramillo, Noel E. Blanco Roa Writing - original draft: Carlos Zuniga Validation: Carlos Zuniga, Jose Luis Jaramillo, Noel E. Blanco Roa Writing – review & editing: Carlos Zuniga, Jose Luis Jaramillo, Noel E. Blanco Roa Data: Carlos Zuniga & Jose Luis Jaramillo Data availability Underlying data Figshare: Data for: Inputs-Oriented VRS DEA in dairy farms, https://doi.org/10.6084/m9.figshare.21836133.v5 . 36 This project contains the following underlying data: • DataforDEAF1000R.cvs • S1.csv (Suplementary Data for VRS Technology with Bootstrap DEA in R Studio) • S2.csv (Suplementary 2 CRS Bootstrap DEA in R Studio) • S3.csv (Dataset used for this study) Extended data Figshare: Data for: Inputs-Oriented VRS DEA in dairy farms, https://doi.org/10.6084/m9.figshare.21836133.v5 . 36 This project contains the following extended data: • Questionnaire MilkProd.pdf (Questionnaire/interview guide translated to English) • Questionnaire de campo_leche.pdf (Questionnaire/interview guide in Spanish) • Table 1.csv • Table 2.csv • Table 3.scv • Table 4.csv • Table 5.csv • Table 6.csv • Table 7.csv • Table 8.csv • Table 9.csv • Table 10.xlsx • Table 11.xlsx • Fig_1.tif • Fig_2.tif • Data for DEA F1000R.xlsx Data are available under the terms of the Creative Commons Attribution 4.0 International license (CC-BY 4.0). References 1. Pérez P, Álvarez C, García J, et al. : Caracterización y problemática de la cadena bovinos de doble propósito en el estado de Veracruz.2004. Reference Source 2. Vargas-Leitón B, Solís-Guzmán O, Sáenz-Segura F, et al. : Eficiencia técnica en hatos lecheros de Costa Rica. Agron. Mesoam. 2015; 26 (1): 1–15. Publisher Full Text 3. Grieg-Gran M, Porras I, Wunder S: How can market mechanisms for forest environmental services help the poor? Preliminary lessons from Latin America. World Dev. 2005; 33 (9): 1511–1527. Publisher Full Text 4. Jiang N, Sharp B: Technical efficiency and technological gap of New Zealand dairy farms: a stochastic meta-frontier model. J. Prod. Anal. 2015; 44 : 39–49. Publisher Full Text 5. Kumbhakar SC, Tsionas EG, Sipiläinen T: Joint estimation of technology choice and technical efficiency: an application to organic and conventional dairy farming. J. Prod. Anal. 2009; 31 : 151–161. Publisher Full Text 6. Farrel MJ: The Measurement of Productive Efficiency. J. R. Stat. Soc., ACXX, Part 3. 1957; 120 : 253–290. Publisher Full Text 7. Zuniga Gonzalez CA, Jaramillo-Villanueva JL: Frontier model of the environmental inefficiency effects on livestock bioeconomy [version 3; peer review: 3 approved; 1 not approved peer review]. F1000Res. 2024; 11 : 1382. Publisher Full Text 8. Delgado C, Rosegrant M, Steinfeld H, et al. : Livestock to 2020: The next food revolution. Outlook Agric. 2001; 30 (1): 27–29. Publisher Full Text 9. Morillo F, Urdaneta F: Sistemas de producción con bovinos para los trópicos americanos. Memorias Conferencia Internacional Sobre la Ganadería en los Trópicos. Gainesville, FL: 1998; pp. 80–104. 10. Servicio de informacion Agricola y pesquera (SIAP): Anuario estadístico de la Secretaria de produccion Agricola.2021. Ultima Vista 26 junio 2023. Servicio de Información Agroalimentaria y Pesquera | Gobierno | gob.mx (www.gob.mx) 11. Altieri MA: Applying agroecology to enhance the productivity of peasant farming systems in Latin America. Environ. Dev. Sustain. 1999; 1 : 197–217. Publisher Full Text 12. FAO: World Agriculture Towards 2030/2050, The (2012). Revision, ESA Working Paper No. 12-03.June 2012. 13. Reardon T, Timmer CP, Berdegue J: The rapid rise of supermarkets in developing countries: Induced organizational, institutional and technological change in agri-food systems. The Transformation of Agri-Food Systems. Routledge; 2012; pp. 71–90. 14. Christiaensen L, Rutledge Z, Taylor JE: The future of work in agri-food. Food Policy. 2021; 99 : 101963. PubMed Abstract | Publisher Full Text | Free Full Text 15. Zúniga-González CA, Durán Zarabozo O, Dios Palomares R, et al. : Estado del arte de la bioeconomía y el cambio climático (No. 1133-2016-92457).2014; pp. 20–329. 16. Dios-Palomares R, Alcaide D, Diz J, et al. : Aspectos medioambientales en los análisis de eficiencia. Rev. iberoam. bioecon. cambio clim. 2015; 1 (1): 88–95. Publisher Full Text 17. Palomares RD, Alcaide D, Diz J, et al. : Análisis de la eficiencia de sistemas agropecuarios en América latina y el Caribe mediante la incorporación de aspectos ambientales. Revista Científica. 2015; 25 (1): 43–50. 18. Dios-Palomares R: Análisis de interpretación de los parámetros de relación de varianzas en el modelo de frontera estocástica. Estudios de Economía Aplicada. 2002; 20 (2): 365–379. 19. Gelan A, Muriithi B: Measuring and explaining technical efficiency of dairy farms: a case study of smallholder farms in East Africa. Agrekon. 2012; 51 (2): 53–74. Publisher Full Text 20. Soltani A, Oukil A, Boutaghane H, Bermad A, et al. : A new methodology for assessing water quality, based on data envelopment analysis: Application to Algerian dams.Ecol. Indic.2021; 106952. 121 . Publisher Full Text 21. Oukil A, Zekri S: Slim: Investigating farming efficiency through a two stage analytical approach: Application to the agricultural sector in Northern Oman. Cornell University; 2021. 22. Zuniga-Gonzalez CA, Moreno-Mayorga LF, Quiroz-Medina CR: Estudio de la eficiencia técnica en escuelas de campo de Nicaragua. Revista Tecnología En Marcha. 2022; 35 (3): 128–140. Publisher Full Text 23. Coelli TJ: A guide to DEAP version 2.1: a data envelopment analysis (computer) program. No 8/96. CEPA working papers. Australia: Department of Econometrics. Centre for Efficiency and Productivity Analysis, University of New England; 1996; 96 (08): 1–49. 1327-435X. 1 863894969 24. Färe R, Grosskopf S, Lovell CAK: Production Frontiers. New York: Cambridge University Press; 1994. 25. Debreu G: The coefficient of resource utilization. Econometrica. 1951; 19 : 273–292. Publisher Full Text 26. Koopmans TC: Efficient allocation of resources. Econometrica. 1951; 19 : 455–465. Publisher Full Text 27. Serrano VC, Blasco OMB: Evaluación de la eficiencia mediante el Análisis Envolvente de Datos: Introducción a los modelos básicos. B-EUMED; 2000. 28. Oviedo W, Rodríguez G: Medición de la eficiencia técnica relativa de las fincas asociadas a Coounión en Guasca Cundinamarca. Revista MVZ Córdoba. 2011; 16 (2): 2616–2627. Publisher Full Text 29. Cooper W, Seiford LM, Karou T: Data envelopment analysis. a comprehensive text with Models, Applications, References and DEA–solver software. New York: Springer; 2007. 30. Cook W, Seiford M: Data envelopment analysis (DEA). Thirty years on. Eur. J. Oper. Res. 2009; 192 : 1–17. Publisher Full Text 31. Charnes A, Cooper WW, Rhodes E: "Measuring the efficiency of decision making units", en. Eur. J. Oper. Res. 1978; 2 : 429–444. Publisher Full Text 32. Charnes A, Cooper WW, Rhodes E: Evaluating program and managerial efficiency: an application of data envelopment analysis to program follow through. Manag. Sci. 1981; 27 (6): 668–697. Publisher Full Text 33. Banker RD, Charnes A, Cooper WW: Some Models for Estimating Technical and Scale Inefficiencies in Data Envelopment Analysis. Manag. Sci. 1984; 30 : 1078–1092. Publisher Full Text 34. Álavarez A, Cristian N, et al. : Eficiencia de escala y su elasticidad en sistemas lecheros de la región sierra centro-norte de Ecuador. Revista Ecuatoriana de Ciencia Animal, [S.l.]. oct. 2022; v. 5 (3): 111–121. 2602-8220. Fecha de acceso: 24 mar. 2023. Reference Source 35. Sperat RR, Paz RG, Robledo W: Productive efficiency in small peasant and capitalist farms. Empirical evidence using DEA. World Journal of Agricultural Sciences. 2008; 4 (5): 583–599. 36. Zuniga-Gonzalez CA, Jaramillo-Villanueva JL: Data for: Inputs-Oriented VRS DEA in dairy farms. figshare. Journal contribution. 2023. Publisher Full Text 37. Moreira V, Bravo B: Un estudio de eficiencia técnica en lecherías usando meta regresión: Una perspectiva internacional. Chilean J. Agric. Res. 2009; 9 : 1–2. 38. Lanteri LN: Productividad, desarrollo tecnológico y eficiencia. la propuesta de los índices Malmquist. Anales de la Asociación Argentina de Economía Política, XXXVII Reunión Anual, Tucumán, Argentina [en línea].2002. Reference Source 39. Robles EA: Crecimiento de la productividad total de los factores en Costa Rica e inestabilidad macroeconómica. Revista de Ciencias Económicas. 2021; 39 (1): 1–24. Publisher Full Text 40. O’Neill L, Rauner M, Heidenberger K, et al. : A cross-national comparison and taxonomy of DEA-based hospital efficiency studies. Socio Econ. Plan. Sci. 2008; 42 (3): 158–189. Publisher Full Text 41. Shephard RW: Theory of cost and production functions. Princeton: Princeton University Press; 1970. 42. Ha M-H, Yang Z:Comparative analysis of port performance indicators: Independency and interdependency. Transp. Res. Part A: Policy Pract. 2017; 103 : 264–278. Publisher Full Text 43. Cullinane K, Wang T-F, Song D-W, et al. :The technical efficiency of container ports: Comparing data envelopment analysis and stochastic frontier analysis. Transp. Res. Part A: Policy Pract. 2006; 40 (4): 354–374. Publisher Full Text 44. Wang T-F, Cullinane K, Song D-W:Container port production efficiency: A comparative study of DEA and FDH approaches. J. East Asia Soc. Transp. Stud. 2003; 5 : 698–701. 45. De Borger B, Kerstens K, Moesen W, et al. :A non-parametric free disposal hull (FDH) approach to technical efficiency: An illustration of radial and graph efficiency measures and some sensitivity results. Swiss J. Econ. Stat. 1994; 130 (4): 647–667. 46. Cesín-Vargas A, Ramírez-Valverde B, Aliphat-Fernández M, et al. : Producción de forraje y ganadería lechera en el suroeste de Tlaxcala, México. Trop. Subtrop. Agroecosystems. 2010; 12 (3): 639–648. 47. Cueva Reyes V, Loaiza Meza A, Espinosa García JA: Tipología de las explotaciones ganaderas de bovinos doble propósito en Sinaloa, México. Revista mexicana de ciencias pecuarias. 2016; 7 (1): 69–83. Recuperado en 13 de julio de 2023, de. Publisher Full Text Reference Source 48. Tim C: A Data Envelopment Analysis (Computer) Program. Australia: Centre for Efficiency and Productivity Analysis Department of Econometrics University of New England Armidale; 1998. 49. Simar L, Wilson PW:Estimation and inference in two-stage, semi-parametric models of production processes. J. Econom. 2007; 136 (1): 31–64. Publisher Full Text 50. Singbo AG, Lansink AO:Lowland farming system inefficiency in Benin (West Africa): directional distance function and truncated bootstrap approach. Food Secur. 2010; 2 : 367–382. Publisher Full Text 51. Singbo AG, Lansink AO, Emvalomatis G:Estimating shadow prices and efficiency analysis of productive inputs and pesticide use of vegetable production. Eur. J. Oper. Res. 2015; 245 (1): 265–272. Publisher Full Text 52. Singbo A, Larue B:Scale economies, technical efficiency, and the sources of total factor productivity growth of Quebec dairy farms. Can. J. Agric. Econ. 2016; 64 (2): 339–363. Publisher Full Text 53. Larue B, Singbo A, Pouliot S:Production rigidity, input lumpiness, efficiency, and the technological hurdle of Quebec dairy farms. Can. J. Agric. Econ. 2017; 65 (4): 613–641. Publisher Full Text 54. Aguilar-Barojas S: Fórmulas para el cálculo de la muestra en investigaciones de salud. Salud en tabasco. 2005; 11 (1-2): 333–338. 55. Coelli TJ: A Guide to DEAP Version 2.1. Data Envelopment Analysis (Computer) Program. Working Study96/08.2016. 56. Mitchell A: The ESRI Guide to GIS Analysis. Vol. 2 . . ESRI Press; 2005. 57. Zuniga-Gonzalez CA, Jaramillo-Villanueva JL: Methodology for Inputs-Oriented VRS DEA in dairy farms. protocols.io. Reference Source 58. Tone K, Tsutsui M: Network DEA: A slacks-based measure approach. Eur. J. Oper. Res. 2009; 197 (1): 243–252. Publisher Full Text 59. Umetsu C: Sustainable farming techniques and farm size for rice smallholders in the Vietnamese Mekong Delta: A slack-based technical efficiency approach. Agric. Ecosyst. Environ. 2022; 326 : 107775. 60. Ali AI, Seiford LM: The mathematical programming approach to efficiency analysis. The measurement of productive efficiency: Techniques and applications. 1993; 120 : 159. 61. Coelli TJ: A Multi-Stage Methodology for the Solution of Oriented DEA Models, mimeo. Armidale: Centre For Efficiency and Productivity Analysis, University of New England; 1997. 62. Rebolledo-Leiva R, Vásquez-Ibarra L, Entrena-Barbero E, et al. : Coupling Material Flow Analysis and Network DEA for the evaluation of eco-efficiency and circularity on dairy farms. Sustain. Prod. Consum. 2022; 31 : 805–817. Publisher Full Text 63. Ferrier GD, Lovell CAK: Measuring Cost Efficiency in Bankings: Econometric and Linear Programming Evidence. J. Econ. 1990; 46 : 229–245. Publisher Full Text 64. Avanzini E: Multistage stochastic programming as flexibility source in highly uncertain environments: its value in an agriculture application.2022. 65. Aigner DJ, Lovell CAK, Schmidt P: Formulation and Estimation of Stochastic Frontier Production Function Models. J. Econ. 1977; 6 : 21–37. Publisher Full Text 66. Battese GE, Coelli TJ: Frontier Production Functions. Technical Efficiency and Panel Data: With Application to Paddy Farmers in India. J. Prod. Anal. 1992; 3 : 153–169. Publisher Full Text 67. Battese GE, Coelli TJ: A stochastic frontier production function incorporating a model for technical inefficiency effects. Working Papers in Econometrics and Applied Statistics No 69. Armidal: Department of Econometrics, The University of New England; 1993. 68. Battese GE, Coelli TJ: Prediction of Firm-Level Technical Efficiencies with a generalized Frontier Production Function and Panel Data. J. Econ. 1988; 38 : 387–399. Publisher Full Text 69. Battese GE, Coelli TJ: A model for Technical Inefficiency Effects in a Stochastic Frontier Production Function for Panel Data. Empir. Econ. 1995; 20 : 325–332. 70. Kremantzis MD, Beullens P, Klein J: A fairer assessment of DMUs in a generalised two-stage DEA structure. Expert Syst. Appl. 2022; 187 : 115921. Publisher Full Text 71. Reifschneider D, Stevenson R: Systematic Departures from the Frontier: A Framework for the Analysis of Firm Inefficiency. Int. Econ. Rev. 1991; 32 : 715–723. Publisher Full Text 72. García AR, Zavala AO: Evaluación de la eficiencia del mezcal en las entidades federativas de México: un análisis de la envolvente de datos (DEA). Inquietud Empresarial. 2022; 22 (1): 83–99. 73. Simar L, Wilson PW:Sensitivity analysis of efficiency scores: How to bootstrap in nonparametric frontier models. Manag. Sci. 1998; 44 (1): 49–61. Publisher Full Text Comments on this article Comments (0) Version 3 VERSION 3 PUBLISHED 28 Jul 2023 ADD YOUR COMMENT Comment Author details Author details 1 Agroecology, National Autonomous University of Nicaragua, Leon, Leon, Leon, 21000, Nicaragua 2 Economy, Postgraduate College, Mexico, Puebla, Cholula, 72760, Mexico 3 Animal Production, National Autonomous University of Nicaragua, Leon, Leon, Leon, 21000, Nicaragua C. A. Zuniga-Gonzalez Roles: Data Curation, Formal Analysis, Methodology, Software, Supervision, Validation, Writing – Review & Editing J. L. Jaramillo-Villanueva Roles: Conceptualization, Investigation, Resources, Visualization, Writing – Original Draft Preparation, Writing – Review & Editing N.E Blanco-Roa Roles: Formal Analysis, Investigation, Visualization, Writing – Original Draft Preparation Competing interests No competing interests were disclosed. Grant information The author(s) declared that no grants were involved in supporting this work. Article Versions (3) version 3 Revised Published: 07 Jan 2025, 12:901 https://doi.org/10.12688/f1000research.132421.3 version 2 Revised Published: 18 Mar 2024, 12:901 https://doi.org/10.12688/f1000research.132421.2 version 1 Published: 28 Jul 2023, 12:901 https://doi.org/10.12688/f1000research.132421.1 Copyright © 2025 Zuniga-Gonzalez CA et al . This is an open access article distributed under the terms of the Creative Commons Attribution License , which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited. Download Export To Sciwheel Bibtex EndNote ProCite Ref. Manager (RIS) Sente metrics Views Downloads F1000Research - - PubMed Central info_outline Data from PMC are received and updated monthly. - - Citations open_in_new 0 open_in_new 0 open_in_new SEE MORE DETAILS CITE how to cite this article Zuniga-Gonzalez CA, Jaramillo-Villanueva JL and Blanco-Roa NE. Inputs-Oriented VRS DEA in dairy farms [version 3; peer review: 2 approved, 1 approved with reservations, 1 not approved] . F1000Research 2025, 12 :901 ( https://doi.org/10.12688/f1000research.132421.3 ) NOTE: If applicable, it is important to ensure the information in square brackets after the title is included in all citations of this article. COPY CITATION DETAILS track receive updates on this article Track an article to receive email alerts on any updates to this article. TRACK THIS ARTICLE Share Open Peer Review Current Reviewer Status: ? Key to Reviewer Statuses VIEW HIDE Approved The paper is scientifically sound in its current form and only minor, if any, improvements are suggested Approved with reservations A number of small changes, sometimes more significant revisions are required to address specific details and improve the papers academic merit. Not approved Fundamental flaws in the paper seriously undermine the findings and conclusions Version 2 VERSION 2 PUBLISHED 18 Mar 2024 Revised Views 0 Cite How to cite this report: Rojas-Rojas MM. Reviewer Report For: Inputs-Oriented VRS DEA in dairy farms [version 3; peer review: 2 approved, 1 approved with reservations, 1 not approved] . F1000Research 2025, 12 :901 ( https://doi.org/10.5256/f1000research.162490.r315210 ) The direct URL for this report is: https://f1000research.com/articles/12-901/v2#referee-response-315210 NOTE: it is important to ensure the information in square brackets after the title is included in this citation. Close Copy Citation Details Reviewer Report 04 Sep 2024 Maria Magdalena Rojas-Rojas , Chapingo Autonomous University, Texcoco,, Mexico Approved VIEWS 0 https://doi.org/10.5256/f1000research.162490.r315210 This study addresses the efficiency of dairy farms in Tlaxcala, Mexico, by measuring mean efficiency for CRS, VRS, and the estimated scale efficiency. With a growing population and adverse climate change conditions, scarce resources must be used more efficiently to ... Continue reading READ ALL This study addresses the efficiency of dairy farms in Tlaxcala, Mexico, by measuring mean efficiency for CRS, VRS, and the estimated scale efficiency. With a growing population and adverse climate change conditions, scarce resources must be used more efficiently to produce food. This research thus contributes to helping production managers identify the causes of low efficiency and productivity in the dairy sector of the region. However, it would be important to expand the recommendations on how public policy decision-makers could use this information. Although the state of Tlaxcala is not representative in terms of milk production, this study can offer as a reference for replication in other production systems, allowing for the establishment of benchmarking. The article is scientifically valid in its current form. The methodology employed is correct and is widely used in other studies. This methodology can be used to generate indicators based on dairy herd size. The study mentions that Cesin-Vargas and Cuevas Reyes identified four types of dairy farms in the study area based on farm size. The results are presented in accordance with the methodology employed, and the conclusions align with the study's objectives. I suggest, if possible, evaluating the results by herd size, as this would allow for reference to the behavior of low efficiency and productivity in dairy herds by size. It would also help identify which farms are efficient and which are weak, allowing for their characterization and use as references for other studies. Is the work clearly and accurately presented and does it cite the current literature? Partly Is the study design appropriate and is the work technically sound? Yes Are sufficient details of methods and analysis provided to allow replication by others? Yes If applicable, is the statistical analysis and its interpretation appropriate? Yes Are all the source data underlying the results available to ensure full reproducibility? No Are the conclusions drawn adequately supported by the results? Yes Competing Interests: No competing interests were disclosed. Reviewer Expertise: Bioeconomy and value chain in the agri-food sector I confirm that I have read this submission and believe that I have an appropriate level of expertise to confirm that it is of an acceptable scientific standard. Close READ LESS CITE CITE HOW TO CITE THIS REPORT Rojas-Rojas MM. Reviewer Report For: Inputs-Oriented VRS DEA in dairy farms [version 3; peer review: 2 approved, 1 approved with reservations, 1 not approved] . F1000Research 2025, 12 :901 ( https://doi.org/10.5256/f1000research.162490.r315210 ) The direct URL for this report is: https://f1000research.com/articles/12-901/v2#referee-response-315210 NOTE: it is important to ensure the information in square brackets after the title is included in all citations of this article. COPY CITATION DETAILS Report a concern Respond or Comment COMMENT ON THIS REPORT Views 0 Cite How to cite this report: Gelan A. Reviewer Report For: Inputs-Oriented VRS DEA in dairy farms [version 3; peer review: 2 approved, 1 approved with reservations, 1 not approved] . F1000Research 2025, 12 :901 ( https://doi.org/10.5256/f1000research.162490.r256988 ) The direct URL for this report is: https://f1000research.com/articles/12-901/v2#referee-response-256988 NOTE: it is important to ensure the information in square brackets after the title is included in this citation. Close Copy Citation Details Reviewer Report 26 Jun 2024 Ayele Gelan , Economics, Kuwait Institute for Scientific Research, Safat, Kuwait Approved VIEWS 0 https://doi.org/10.5256/f1000research.162490.r256988 The paper has undergone substantial revisions, addressing previous concerns. Therefore, ... Continue reading READ ALL The paper has undergone substantial revisions, addressing previous concerns. Therefore, I confirm that the latest version can be approved for indexing. Competing Interests: No competing interests were disclosed. Reviewer Expertise: Economics, Agriculture, Environment I confirm that I have read this submission and believe that I have an appropriate level of expertise to confirm that it is of an acceptable scientific standard. Close READ LESS CITE CITE HOW TO CITE THIS REPORT Gelan A. Reviewer Report For: Inputs-Oriented VRS DEA in dairy farms [version 3; peer review: 2 approved, 1 approved with reservations, 1 not approved] . F1000Research 2025, 12 :901 ( https://doi.org/10.5256/f1000research.162490.r256988 ) The direct URL for this report is: https://f1000research.com/articles/12-901/v2#referee-response-256988 NOTE: it is important to ensure the information in square brackets after the title is included in all citations of this article. COPY CITATION DETAILS Report a concern Respond or Comment COMMENT ON THIS REPORT Version 1 VERSION 1 PUBLISHED 28 Jul 2023 Views 0 Cite How to cite this report: Oukil A. Reviewer Report For: Inputs-Oriented VRS DEA in dairy farms [version 3; peer review: 2 approved, 1 approved with reservations, 1 not approved] . F1000Research 2025, 12 :901 ( https://doi.org/10.5256/f1000research.145337.r235362 ) The direct URL for this report is: https://f1000research.com/articles/12-901/v1#referee-response-235362 NOTE: it is important to ensure the information in square brackets after the title is included in this citation. Close Copy Citation Details Reviewer Report 15 Feb 2024 Amar Oukil , College of Economics & Political Science, Sultan Qaboos University, Muscat, Muscat Governorate, Oman Approved with Reservations VIEWS 0 https://doi.org/10.5256/f1000research.145337.r235362 The reviewer read with a lot of interest the manuscript. The manuscript is not well written. It requires an in-depth polishing for English as well as a better flow of ideas. Some other technical flaws that need to be addressed ... Continue reading READ ALL The reviewer read with a lot of interest the manuscript. The manuscript is not well written. It requires an in-depth polishing for English as well as a better flow of ideas. Some other technical flaws that need to be addressed include: 1) All over the manuscript, Data Envelopment Analysis instead of data envelope analysis or envelope data analysis 2) Scale efficiency instead of Efficiency of scale 3) In the last sentence of page 4 “achieve” should be “use” 4) In the first paragraph of page 5, proportional is valid for only CRS model and it does not apply for VRS. Under VRS assumption, proportionality does not apply anywhere over the manuscript. 5) The authors have chosen an input-orientation for the study. What is the justification for such a choice? 6) The paragraph before model (1) presents several inaccurate statements and it must be revised with a lot of care. 7) In model (2), the objective and the first constraints are wrong. 8) What is the purpose of Table 1? 9) There seems to be a lot of confusion about the models used. The authors used the standard DEA VRS model but, at different levels, they mention the radial model and the cross-efficiency model and other information that might not be useful for practitioners. Since the paper’s contribution is mainly an application, it is better to remove any theoretical concept and formulas that are not directly related to the methodology used. 10)In the efficiency results, it is also important to identify the benchmarking farms, which should necessarily be strongly efficient. As such, the authors should clearly distinguish the weakly and the strongly efficient farms by using the slack values. See, e.g., ref[2]and [1] 11)In the application, it is enough to mention the software used, without more details on how it has been implemented on the data sample. 12) The paper is mostly an application of DEA, which is expected to be support decision making. Accordingly, one of the key flaws of the study is the absence of Managerial implications at both farmers and policy makers’ levels. A section fully dedicated to these aspects is required. Since the paper is only an application of an already established methodology, I would also suggest changing the title to: Performance analysis of the Mexican dairy farms : A standard DEA approach Is the work clearly and accurately presented and does it cite the current literature? Yes Is the study design appropriate and is the work technically sound? Partly Are sufficient details of methods and analysis provided to allow replication by others? Partly If applicable, is the statistical analysis and its interpretation appropriate? Partly Are all the source data underlying the results available to ensure full reproducibility? No Are the conclusions drawn adequately supported by the results? No References 1. Soltani A, Oukil A, Boutaghane H, Bermad A, et al.: A new methodology for assessing water quality, based on data envelopment analysis: Application to Algerian dams. Ecological Indicators . 2021; 121 . Publisher Full Text 2. Amar Oukil, Slim: Investigating farming efficiency through a two stage analytical approach: Application to the agricultural sector in Northern Oman. Cornell university . 2021. Competing Interests: No competing interests were disclosed. Reviewer Expertise: Data envelop,emt analysis I confirm that I have read this submission and believe that I have an appropriate level of expertise to confirm that it is of an acceptable scientific standard, however I have significant reservations, as outlined above. Close READ LESS CITE CITE HOW TO CITE THIS REPORT Oukil A. Reviewer Report For: Inputs-Oriented VRS DEA in dairy farms [version 3; peer review: 2 approved, 1 approved with reservations, 1 not approved] . F1000Research 2025, 12 :901 ( https://doi.org/10.5256/f1000research.145337.r235362 ) The direct URL for this report is: https://f1000research.com/articles/12-901/v1#referee-response-235362 NOTE: it is important to ensure the information in square brackets after the title is included in all citations of this article. COPY CITATION DETAILS Report a concern Author Response 13 Apr 2024 C. A. Zuniga-Gonzalez , Agroecology, National Autonomous University of Nicaragua, Leon, Leon, 21000, Nicaragua 13 Apr 2024 Author Response Response to Reviewer # 3 Comments: [1] Regarding the terminology, we will correct "Data Envelopment Analysis" to "data envelopment analysis" throughout the manuscript for consistency. [2] We will adjust ... Continue reading Response to Reviewer # 3 Comments: [1] Regarding the terminology, we will correct "Data Envelopment Analysis" to "data envelopment analysis" throughout the manuscript for consistency. [2] We will adjust "Efficiency of scale" to "Scale efficiency" as per your suggestion. We will correct the typo in the last sentence of page 4 from "achieve" to "use." [3] Thank you for pointing out the distinction between proportional validity for CRS and its inapplicability for VRS. We will ensure this is accurately reflected, especially in the first paragraph of page 5. [4] We will provide a clear justification for choosing an input-orientation for the study to address this concern. [5] We will carefully revise the paragraph before model (1) to rectify any inaccuracies. [6] We will review and correct the objective and constraints in model (2) as per your guidance. [7] Table 1 will be revised to explicitly state its purpose. [8] We will streamline the discussion on the models used, focusing only on those directly relevant to the methodology employed in the study, as suggested. [9] We will distinguish between weakly and strongly efficient farms in the efficiency results, incorporating benchmarking farms and slack values as per your recommendation. [10] We will limit the details on software implementation to mention the software used without elaborate explanations. [11] A dedicated section providing managerial implications for both farmers and policymakers will be included in the manuscript. Regarding your suggestion to change the title, we will consider it in light of the paper's focus on a standard DEA approach for analyzing Mexican dairy farms. [12] Additionally, we will ensure that the literature cited is accurately reflected and that any missing details regarding methods, analysis, and data reproducibility are adequately addressed. We added the references suggested for you. Thank you for your valuable feedback, which will greatly improve the quality and clarity of our manuscript. Response to Reviewer # 3 Comments: [1] Regarding the terminology, we will correct "Data Envelopment Analysis" to "data envelopment analysis" throughout the manuscript for consistency. [2] We will adjust "Efficiency of scale" to "Scale efficiency" as per your suggestion. We will correct the typo in the last sentence of page 4 from "achieve" to "use." [3] Thank you for pointing out the distinction between proportional validity for CRS and its inapplicability for VRS. We will ensure this is accurately reflected, especially in the first paragraph of page 5. [4] We will provide a clear justification for choosing an input-orientation for the study to address this concern. [5] We will carefully revise the paragraph before model (1) to rectify any inaccuracies. [6] We will review and correct the objective and constraints in model (2) as per your guidance. [7] Table 1 will be revised to explicitly state its purpose. [8] We will streamline the discussion on the models used, focusing only on those directly relevant to the methodology employed in the study, as suggested. [9] We will distinguish between weakly and strongly efficient farms in the efficiency results, incorporating benchmarking farms and slack values as per your recommendation. [10] We will limit the details on software implementation to mention the software used without elaborate explanations. [11] A dedicated section providing managerial implications for both farmers and policymakers will be included in the manuscript. Regarding your suggestion to change the title, we will consider it in light of the paper's focus on a standard DEA approach for analyzing Mexican dairy farms. [12] Additionally, we will ensure that the literature cited is accurately reflected and that any missing details regarding methods, analysis, and data reproducibility are adequately addressed. We added the references suggested for you. Thank you for your valuable feedback, which will greatly improve the quality and clarity of our manuscript. Competing Interests: No competing interests were disclosed. Close Report a concern Respond or Comment COMMENTS ON THIS REPORT Author Response 13 Apr 2024 C. A. Zuniga-Gonzalez , Agroecology, National Autonomous University of Nicaragua, Leon, Leon, 21000, Nicaragua 13 Apr 2024 Author Response Response to Reviewer # 3 Comments: [1] Regarding the terminology, we will correct "Data Envelopment Analysis" to "data envelopment analysis" throughout the manuscript for consistency. [2] We will adjust ... Continue reading Response to Reviewer # 3 Comments: [1] Regarding the terminology, we will correct "Data Envelopment Analysis" to "data envelopment analysis" throughout the manuscript for consistency. [2] We will adjust "Efficiency of scale" to "Scale efficiency" as per your suggestion. We will correct the typo in the last sentence of page 4 from "achieve" to "use." [3] Thank you for pointing out the distinction between proportional validity for CRS and its inapplicability for VRS. We will ensure this is accurately reflected, especially in the first paragraph of page 5. [4] We will provide a clear justification for choosing an input-orientation for the study to address this concern. [5] We will carefully revise the paragraph before model (1) to rectify any inaccuracies. [6] We will review and correct the objective and constraints in model (2) as per your guidance. [7] Table 1 will be revised to explicitly state its purpose. [8] We will streamline the discussion on the models used, focusing only on those directly relevant to the methodology employed in the study, as suggested. [9] We will distinguish between weakly and strongly efficient farms in the efficiency results, incorporating benchmarking farms and slack values as per your recommendation. [10] We will limit the details on software implementation to mention the software used without elaborate explanations. [11] A dedicated section providing managerial implications for both farmers and policymakers will be included in the manuscript. Regarding your suggestion to change the title, we will consider it in light of the paper's focus on a standard DEA approach for analyzing Mexican dairy farms. [12] Additionally, we will ensure that the literature cited is accurately reflected and that any missing details regarding methods, analysis, and data reproducibility are adequately addressed. We added the references suggested for you. Thank you for your valuable feedback, which will greatly improve the quality and clarity of our manuscript. Response to Reviewer # 3 Comments: [1] Regarding the terminology, we will correct "Data Envelopment Analysis" to "data envelopment analysis" throughout the manuscript for consistency. [2] We will adjust "Efficiency of scale" to "Scale efficiency" as per your suggestion. We will correct the typo in the last sentence of page 4 from "achieve" to "use." [3] Thank you for pointing out the distinction between proportional validity for CRS and its inapplicability for VRS. We will ensure this is accurately reflected, especially in the first paragraph of page 5. [4] We will provide a clear justification for choosing an input-orientation for the study to address this concern. [5] We will carefully revise the paragraph before model (1) to rectify any inaccuracies. [6] We will review and correct the objective and constraints in model (2) as per your guidance. [7] Table 1 will be revised to explicitly state its purpose. [8] We will streamline the discussion on the models used, focusing only on those directly relevant to the methodology employed in the study, as suggested. [9] We will distinguish between weakly and strongly efficient farms in the efficiency results, incorporating benchmarking farms and slack values as per your recommendation. [10] We will limit the details on software implementation to mention the software used without elaborate explanations. [11] A dedicated section providing managerial implications for both farmers and policymakers will be included in the manuscript. Regarding your suggestion to change the title, we will consider it in light of the paper's focus on a standard DEA approach for analyzing Mexican dairy farms. [12] Additionally, we will ensure that the literature cited is accurately reflected and that any missing details regarding methods, analysis, and data reproducibility are adequately addressed. We added the references suggested for you. Thank you for your valuable feedback, which will greatly improve the quality and clarity of our manuscript. Competing Interests: No competing interests were disclosed. Close Report a concern COMMENT ON THIS REPORT Views 0 Cite How to cite this report: Singbo A. Reviewer Report For: Inputs-Oriented VRS DEA in dairy farms [version 3; peer review: 2 approved, 1 approved with reservations, 1 not approved] . F1000Research 2025, 12 :901 ( https://doi.org/10.5256/f1000research.145337.r213132 ) The direct URL for this report is: https://f1000research.com/articles/12-901/v1#referee-response-213132 NOTE: it is important to ensure the information in square brackets after the title is included in this citation. Close Copy Citation Details Reviewer Report 22 Jan 2024 Alphonse Singbo , Universite Laval, Québec City, Québec, Canada Not Approved VIEWS 0 https://doi.org/10.5256/f1000research.145337.r213132 Reviewer Inputs-oriented VRS DEA in dairy farms C.A. Zuniga-Gonzalez, J.L. Jaramillo-Villanueva, N.E. Blanco-Roa Summary This article uses the non-parametric DEA to investigate the technical efficiency measures of Tlaxcala’s dairy farm on a sample of ... Continue reading READ ALL Reviewer Inputs-oriented VRS DEA in dairy farms C.A. Zuniga-Gonzalez, J.L. Jaramillo-Villanueva, N.E. Blanco-Roa Summary This article uses the non-parametric DEA to investigate the technical efficiency measures of Tlaxcala’s dairy farm on a sample of 102 farms. Authors apply an input-oriented DEA and find that 50% of the farms are technically efficient and operating at the production frontier. In addition, compute the slacks of input uses. However, this methodology is very old and not up to date and has been criticized in recent literatures. The paper lacks for consistency and does not give additional contribution to the literature in this field. Many papers have covered this topic in international agricultural economics journal. In addition, the paper has several typos and formulations and need to go through serious language editing. Even authors cannot properly define the DEA in the abstract and in the manuscript. Main comments The non-parametric DEA has several limitations that have been covered in efficiency and productivity literatures like Simar and Wilson (2007)[Ref1] with empirical applications in Singbo et al. (2010; 2015, 2016, 2017) and others[Ref2] Since dairy farmers in Mexico are not looking only to minimize the cost of inputs but also to maximize their output especially in this financial turmoil that farmers are facing; I would suggest authors to apply the directional distance function that maximize profit. I would also suggest authors to look for the bootstrapping approach to correct for the bias of the non-parametric DEA. I would suggest authors to review deeply the paper and follow recent improvement in empirical literatures as well as in dairy sector. Is the work clearly and accurately presented and does it cite the current literature? No Is the study design appropriate and is the work technically sound? No Are sufficient details of methods and analysis provided to allow replication by others? No If applicable, is the statistical analysis and its interpretation appropriate? No Are all the source data underlying the results available to ensure full reproducibility? No Are the conclusions drawn adequately supported by the results? No References 1. Simar L, Wilson P: Estimation and inference in two-stage, semi-parametric models of production processes. Journal of Econometrics . 2007; 136 (1): 31-64 Publisher Full Text 2. Singbo A, Lansink A, Emvalomatis G: Estimating shadow prices and efficiency analysis of productive inputs and pesticide use of vegetable production. European Journal of Operational Research . 2015; 245 (1): 265-272 Publisher Full Text Competing Interests: No competing interests were disclosed. Reviewer Expertise: Agricultural economcs; production economics; productivity and efficiency analysis. I confirm that I have read this submission and believe that I have an appropriate level of expertise to state that I do not consider it to be of an acceptable scientific standard, for reasons outlined above. Close READ LESS CITE CITE HOW TO CITE THIS REPORT Singbo A. Reviewer Report For: Inputs-Oriented VRS DEA in dairy farms [version 3; peer review: 2 approved, 1 approved with reservations, 1 not approved] . F1000Research 2025, 12 :901 ( https://doi.org/10.5256/f1000research.145337.r213132 ) The direct URL for this report is: https://f1000research.com/articles/12-901/v1#referee-response-213132 NOTE: it is important to ensure the information in square brackets after the title is included in all citations of this article. COPY CITATION DETAILS Report a concern Author Response 13 Apr 2024 C. A. Zuniga-Gonzalez , Agroecology, National Autonomous University of Nicaragua, Leon, Leon, 21000, Nicaragua 13 Apr 2024 Author Response Reviewer 2 Reviewer Report 22 Jan 2024 | for Version 1 Alphonse Singbo, Universite Laval, Québec City, Québec, Canada NOT APPROVED Reviewer 2 Inputs-oriented VRS DEA in dairy farms C.A. ... Continue reading Reviewer 2 Reviewer Report 22 Jan 2024 | for Version 1 Alphonse Singbo, Universite Laval, Québec City, Québec, Canada NOT APPROVED Reviewer 2 Inputs-oriented VRS DEA in dairy farms C.A. Zuniga-Gonzalez, J.L. Jaramillo-Villanueva, N.E. Blanco-Roa Summary [1] This article uses the non-parametric DEA to investigate the technical efficiency measures of Tlaxcala’s dairy farm on a sample of 102 farms. Authors apply an input-oriented DEA and find that 50% of the farms are technically efficient and operating at the production frontier. In addition, compute the slacks of input uses. However, this methodology is very old and not up to date and has been criticized in recent literatures. The paper lacks for consistency and does not give additional contribution to the literature in this field. Many papers have covered this topic in international agricultural economics journal. In addition, the paper has several typos and formulations and need to go through serious language editing. Even authors cannot properly define the DEA in the abstract and in the manuscript. Response: Thank you for taking the time to review our article and providing valuable feedback. We appreciate your thoughtful comments and acknowledge the concerns raised regarding the methodology used in our study. We understand and respect your perspective on the non-parametric DEA methodology, and we are grateful for your suggestion to consider more approaches that are recent. We will carefully assess the literature you referred to and explore potential updates to enhance the robustness of our analysis. Regarding the consistency and contribution to the literature, we will revisit our paper to ensure a more cohesive presentation of our findings. Your observation on the extensive coverage of this topic in international agricultural economics journals is noted, and we will work towards emphasizing the unique aspects of our study that contribute meaningfully to the existing body of knowledge. We also appreciate your attention to language editing concerns, typos, and formulations. We will conduct a thorough review and editing process to address these issues and ensure the clarity and precision of our manuscript. Your constructive feedback is invaluable to us, and we are committed to making the necessary improvements to enhance the overall quality of our work. We look forward to submitting a revised version that addresses these concerns and better aligns with the standards of the field. References add to review literature [62] Simar, L., & Wilson, P. W. (2007). Estimation and inference in two-stage, semi-parametric models of production processes. Journal of econometrics, 136(1), 31-64. [2] Main comments The non-parametric DEA has several limitations that have been covered in efficiency and productivity literatures like Simar and Wilson (2007)[Ref1] with empirical applications in Singbo et al. (2010; 2015, 2016, 2017) and others[Ref2] Response: In the literature review section, I added these references and incorporated three additional paragraphs, also en results section. [3] Since dairy farmers in Mexico are not looking only to minimize the cost of inputs but also to maximize their output especially in this financial turmoil that farmers are facing; I would suggest authors to apply the directional distance function that maximize profit. I would also suggest authors to look for the bootstrapping approach to correct for the bias of the non-parametric DEA. I would suggest authors to review deeply the paper and follow recent improvement in empirical literatures as well as in dairy sector. Response: Thanks for this observation; we have been address this as following: Directional Distance Function: We have thoroughly investigated the application of the directional distance function in the context of dairy farming and have found it to be a meaningful enhancement to our methodology. The revised manuscript now incorporates a detailed explanation of how the directional distance function aligns seamlessly with our study objectives, specifically focusing on maximizing profits. Although the purpose of our research was to consider costs based on inputs. Bootstrapping Approach: Recognizing the importance of addressing bias in non-parametric DEA, we have explored and implemented a bootstrapping approach in our analysis. A dedicated section in the methodology now outlines the utilization of the bootstrapping technique, providing transparency in correcting biases and ensuring the robustness of our findings. In-Depth Review and Recent Literature: A comprehensive review of the entire paper has been conducted, with a keen focus on recent improvements in empirical literature and advancements in the dairy sector. The literature review section has been updated to incorporate recent insights, ensuring that our study remains current and aligned with the latest developments in the field. These revisions have significantly strengthened our manuscript, enhancing its alignment with recent advancements and addressing the specific concerns raised by the reviewer. We believe these changes contribute positively to the overall quality and relevance of our research. Thank you for your continued support and guidance throughout this process. We look forward to further feedback and the opportunity to contribute to the advancement of knowledge in our field. [4] References 1. Simar L, Wilson P: Estimation and inference in two-stage, semi-parametric models of production processes. Journal of Econometrics. 2007; 136 (1): 31-64 Publisher Full Text 2. Singbo A, Lansink A, Emvalomatis G: Estimating shadow prices and efficiency analysis of productive inputs and pesticide use of vegetable production. European Journal of Operational Research. 2015; 245 (1): 265-272 Publisher Full Text Response: We added These references. Reviewer 2 Reviewer Report 22 Jan 2024 | for Version 1 Alphonse Singbo, Universite Laval, Québec City, Québec, Canada NOT APPROVED Reviewer 2 Inputs-oriented VRS DEA in dairy farms C.A. Zuniga-Gonzalez, J.L. Jaramillo-Villanueva, N.E. Blanco-Roa Summary [1] This article uses the non-parametric DEA to investigate the technical efficiency measures of Tlaxcala’s dairy farm on a sample of 102 farms. Authors apply an input-oriented DEA and find that 50% of the farms are technically efficient and operating at the production frontier. In addition, compute the slacks of input uses. However, this methodology is very old and not up to date and has been criticized in recent literatures. The paper lacks for consistency and does not give additional contribution to the literature in this field. Many papers have covered this topic in international agricultural economics journal. In addition, the paper has several typos and formulations and need to go through serious language editing. Even authors cannot properly define the DEA in the abstract and in the manuscript. Response: Thank you for taking the time to review our article and providing valuable feedback. We appreciate your thoughtful comments and acknowledge the concerns raised regarding the methodology used in our study. We understand and respect your perspective on the non-parametric DEA methodology, and we are grateful for your suggestion to consider more approaches that are recent. We will carefully assess the literature you referred to and explore potential updates to enhance the robustness of our analysis. Regarding the consistency and contribution to the literature, we will revisit our paper to ensure a more cohesive presentation of our findings. Your observation on the extensive coverage of this topic in international agricultural economics journals is noted, and we will work towards emphasizing the unique aspects of our study that contribute meaningfully to the existing body of knowledge. We also appreciate your attention to language editing concerns, typos, and formulations. We will conduct a thorough review and editing process to address these issues and ensure the clarity and precision of our manuscript. Your constructive feedback is invaluable to us, and we are committed to making the necessary improvements to enhance the overall quality of our work. We look forward to submitting a revised version that addresses these concerns and better aligns with the standards of the field. References add to review literature [62] Simar, L., & Wilson, P. W. (2007). Estimation and inference in two-stage, semi-parametric models of production processes. Journal of econometrics, 136(1), 31-64. [2] Main comments The non-parametric DEA has several limitations that have been covered in efficiency and productivity literatures like Simar and Wilson (2007)[Ref1] with empirical applications in Singbo et al. (2010; 2015, 2016, 2017) and others[Ref2] Response: In the literature review section, I added these references and incorporated three additional paragraphs, also en results section. [3] Since dairy farmers in Mexico are not looking only to minimize the cost of inputs but also to maximize their output especially in this financial turmoil that farmers are facing; I would suggest authors to apply the directional distance function that maximize profit. I would also suggest authors to look for the bootstrapping approach to correct for the bias of the non-parametric DEA. I would suggest authors to review deeply the paper and follow recent improvement in empirical literatures as well as in dairy sector. Response: Thanks for this observation; we have been address this as following: Directional Distance Function: We have thoroughly investigated the application of the directional distance function in the context of dairy farming and have found it to be a meaningful enhancement to our methodology. The revised manuscript now incorporates a detailed explanation of how the directional distance function aligns seamlessly with our study objectives, specifically focusing on maximizing profits. Although the purpose of our research was to consider costs based on inputs. Bootstrapping Approach: Recognizing the importance of addressing bias in non-parametric DEA, we have explored and implemented a bootstrapping approach in our analysis. A dedicated section in the methodology now outlines the utilization of the bootstrapping technique, providing transparency in correcting biases and ensuring the robustness of our findings. In-Depth Review and Recent Literature: A comprehensive review of the entire paper has been conducted, with a keen focus on recent improvements in empirical literature and advancements in the dairy sector. The literature review section has been updated to incorporate recent insights, ensuring that our study remains current and aligned with the latest developments in the field. These revisions have significantly strengthened our manuscript, enhancing its alignment with recent advancements and addressing the specific concerns raised by the reviewer. We believe these changes contribute positively to the overall quality and relevance of our research. Thank you for your continued support and guidance throughout this process. We look forward to further feedback and the opportunity to contribute to the advancement of knowledge in our field. [4] References 1. Simar L, Wilson P: Estimation and inference in two-stage, semi-parametric models of production processes. Journal of Econometrics. 2007; 136 (1): 31-64 Publisher Full Text 2. Singbo A, Lansink A, Emvalomatis G: Estimating shadow prices and efficiency analysis of productive inputs and pesticide use of vegetable production. European Journal of Operational Research. 2015; 245 (1): 265-272 Publisher Full Text Response: We added These references. Competing Interests: We declare that not have competing interest. Close Report a concern Respond or Comment COMMENTS ON THIS REPORT Author Response 13 Apr 2024 C. A. Zuniga-Gonzalez , Agroecology, National Autonomous University of Nicaragua, Leon, Leon, 21000, Nicaragua 13 Apr 2024 Author Response Reviewer 2 Reviewer Report 22 Jan 2024 | for Version 1 Alphonse Singbo, Universite Laval, Québec City, Québec, Canada NOT APPROVED Reviewer 2 Inputs-oriented VRS DEA in dairy farms C.A. ... Continue reading Reviewer 2 Reviewer Report 22 Jan 2024 | for Version 1 Alphonse Singbo, Universite Laval, Québec City, Québec, Canada NOT APPROVED Reviewer 2 Inputs-oriented VRS DEA in dairy farms C.A. Zuniga-Gonzalez, J.L. Jaramillo-Villanueva, N.E. Blanco-Roa Summary [1] This article uses the non-parametric DEA to investigate the technical efficiency measures of Tlaxcala’s dairy farm on a sample of 102 farms. Authors apply an input-oriented DEA and find that 50% of the farms are technically efficient and operating at the production frontier. In addition, compute the slacks of input uses. However, this methodology is very old and not up to date and has been criticized in recent literatures. The paper lacks for consistency and does not give additional contribution to the literature in this field. Many papers have covered this topic in international agricultural economics journal. In addition, the paper has several typos and formulations and need to go through serious language editing. Even authors cannot properly define the DEA in the abstract and in the manuscript. Response: Thank you for taking the time to review our article and providing valuable feedback. We appreciate your thoughtful comments and acknowledge the concerns raised regarding the methodology used in our study. We understand and respect your perspective on the non-parametric DEA methodology, and we are grateful for your suggestion to consider more approaches that are recent. We will carefully assess the literature you referred to and explore potential updates to enhance the robustness of our analysis. Regarding the consistency and contribution to the literature, we will revisit our paper to ensure a more cohesive presentation of our findings. Your observation on the extensive coverage of this topic in international agricultural economics journals is noted, and we will work towards emphasizing the unique aspects of our study that contribute meaningfully to the existing body of knowledge. We also appreciate your attention to language editing concerns, typos, and formulations. We will conduct a thorough review and editing process to address these issues and ensure the clarity and precision of our manuscript. Your constructive feedback is invaluable to us, and we are committed to making the necessary improvements to enhance the overall quality of our work. We look forward to submitting a revised version that addresses these concerns and better aligns with the standards of the field. References add to review literature [62] Simar, L., & Wilson, P. W. (2007). Estimation and inference in two-stage, semi-parametric models of production processes. Journal of econometrics, 136(1), 31-64. [2] Main comments The non-parametric DEA has several limitations that have been covered in efficiency and productivity literatures like Simar and Wilson (2007)[Ref1] with empirical applications in Singbo et al. (2010; 2015, 2016, 2017) and others[Ref2] Response: In the literature review section, I added these references and incorporated three additional paragraphs, also en results section. [3] Since dairy farmers in Mexico are not looking only to minimize the cost of inputs but also to maximize their output especially in this financial turmoil that farmers are facing; I would suggest authors to apply the directional distance function that maximize profit. I would also suggest authors to look for the bootstrapping approach to correct for the bias of the non-parametric DEA. I would suggest authors to review deeply the paper and follow recent improvement in empirical literatures as well as in dairy sector. Response: Thanks for this observation; we have been address this as following: Directional Distance Function: We have thoroughly investigated the application of the directional distance function in the context of dairy farming and have found it to be a meaningful enhancement to our methodology. The revised manuscript now incorporates a detailed explanation of how the directional distance function aligns seamlessly with our study objectives, specifically focusing on maximizing profits. Although the purpose of our research was to consider costs based on inputs. Bootstrapping Approach: Recognizing the importance of addressing bias in non-parametric DEA, we have explored and implemented a bootstrapping approach in our analysis. A dedicated section in the methodology now outlines the utilization of the bootstrapping technique, providing transparency in correcting biases and ensuring the robustness of our findings. In-Depth Review and Recent Literature: A comprehensive review of the entire paper has been conducted, with a keen focus on recent improvements in empirical literature and advancements in the dairy sector. The literature review section has been updated to incorporate recent insights, ensuring that our study remains current and aligned with the latest developments in the field. These revisions have significantly strengthened our manuscript, enhancing its alignment with recent advancements and addressing the specific concerns raised by the reviewer. We believe these changes contribute positively to the overall quality and relevance of our research. Thank you for your continued support and guidance throughout this process. We look forward to further feedback and the opportunity to contribute to the advancement of knowledge in our field. [4] References 1. Simar L, Wilson P: Estimation and inference in two-stage, semi-parametric models of production processes. Journal of Econometrics. 2007; 136 (1): 31-64 Publisher Full Text 2. Singbo A, Lansink A, Emvalomatis G: Estimating shadow prices and efficiency analysis of productive inputs and pesticide use of vegetable production. European Journal of Operational Research. 2015; 245 (1): 265-272 Publisher Full Text Response: We added These references. Reviewer 2 Reviewer Report 22 Jan 2024 | for Version 1 Alphonse Singbo, Universite Laval, Québec City, Québec, Canada NOT APPROVED Reviewer 2 Inputs-oriented VRS DEA in dairy farms C.A. Zuniga-Gonzalez, J.L. Jaramillo-Villanueva, N.E. Blanco-Roa Summary [1] This article uses the non-parametric DEA to investigate the technical efficiency measures of Tlaxcala’s dairy farm on a sample of 102 farms. Authors apply an input-oriented DEA and find that 50% of the farms are technically efficient and operating at the production frontier. In addition, compute the slacks of input uses. However, this methodology is very old and not up to date and has been criticized in recent literatures. The paper lacks for consistency and does not give additional contribution to the literature in this field. Many papers have covered this topic in international agricultural economics journal. In addition, the paper has several typos and formulations and need to go through serious language editing. Even authors cannot properly define the DEA in the abstract and in the manuscript. Response: Thank you for taking the time to review our article and providing valuable feedback. We appreciate your thoughtful comments and acknowledge the concerns raised regarding the methodology used in our study. We understand and respect your perspective on the non-parametric DEA methodology, and we are grateful for your suggestion to consider more approaches that are recent. We will carefully assess the literature you referred to and explore potential updates to enhance the robustness of our analysis. Regarding the consistency and contribution to the literature, we will revisit our paper to ensure a more cohesive presentation of our findings. Your observation on the extensive coverage of this topic in international agricultural economics journals is noted, and we will work towards emphasizing the unique aspects of our study that contribute meaningfully to the existing body of knowledge. We also appreciate your attention to language editing concerns, typos, and formulations. We will conduct a thorough review and editing process to address these issues and ensure the clarity and precision of our manuscript. Your constructive feedback is invaluable to us, and we are committed to making the necessary improvements to enhance the overall quality of our work. We look forward to submitting a revised version that addresses these concerns and better aligns with the standards of the field. References add to review literature [62] Simar, L., & Wilson, P. W. (2007). Estimation and inference in two-stage, semi-parametric models of production processes. Journal of econometrics, 136(1), 31-64. [2] Main comments The non-parametric DEA has several limitations that have been covered in efficiency and productivity literatures like Simar and Wilson (2007)[Ref1] with empirical applications in Singbo et al. (2010; 2015, 2016, 2017) and others[Ref2] Response: In the literature review section, I added these references and incorporated three additional paragraphs, also en results section. [3] Since dairy farmers in Mexico are not looking only to minimize the cost of inputs but also to maximize their output especially in this financial turmoil that farmers are facing; I would suggest authors to apply the directional distance function that maximize profit. I would also suggest authors to look for the bootstrapping approach to correct for the bias of the non-parametric DEA. I would suggest authors to review deeply the paper and follow recent improvement in empirical literatures as well as in dairy sector. Response: Thanks for this observation; we have been address this as following: Directional Distance Function: We have thoroughly investigated the application of the directional distance function in the context of dairy farming and have found it to be a meaningful enhancement to our methodology. The revised manuscript now incorporates a detailed explanation of how the directional distance function aligns seamlessly with our study objectives, specifically focusing on maximizing profits. Although the purpose of our research was to consider costs based on inputs. Bootstrapping Approach: Recognizing the importance of addressing bias in non-parametric DEA, we have explored and implemented a bootstrapping approach in our analysis. A dedicated section in the methodology now outlines the utilization of the bootstrapping technique, providing transparency in correcting biases and ensuring the robustness of our findings. In-Depth Review and Recent Literature: A comprehensive review of the entire paper has been conducted, with a keen focus on recent improvements in empirical literature and advancements in the dairy sector. The literature review section has been updated to incorporate recent insights, ensuring that our study remains current and aligned with the latest developments in the field. These revisions have significantly strengthened our manuscript, enhancing its alignment with recent advancements and addressing the specific concerns raised by the reviewer. We believe these changes contribute positively to the overall quality and relevance of our research. Thank you for your continued support and guidance throughout this process. We look forward to further feedback and the opportunity to contribute to the advancement of knowledge in our field. [4] References 1. Simar L, Wilson P: Estimation and inference in two-stage, semi-parametric models of production processes. Journal of Econometrics. 2007; 136 (1): 31-64 Publisher Full Text 2. Singbo A, Lansink A, Emvalomatis G: Estimating shadow prices and efficiency analysis of productive inputs and pesticide use of vegetable production. European Journal of Operational Research. 2015; 245 (1): 265-272 Publisher Full Text Response: We added These references. Competing Interests: We declare that not have competing interest. Close Report a concern COMMENT ON THIS REPORT Views 0 Cite How to cite this report: Gelan A. Reviewer Report For: Inputs-Oriented VRS DEA in dairy farms [version 3; peer review: 2 approved, 1 approved with reservations, 1 not approved] . F1000Research 2025, 12 :901 ( https://doi.org/10.5256/f1000research.145337.r213133 ) The direct URL for this report is: https://f1000research.com/articles/12-901/v1#referee-response-213133 NOTE: it is important to ensure the information in square brackets after the title is included in this citation. Close Copy Citation Details Reviewer Report 30 Oct 2023 Ayele Gelan , Economics, Kuwait Institute for Scientific Research, Safat, Kuwait Not Approved VIEWS 0 https://doi.org/10.5256/f1000research.145337.r213133 This paper concerned itself with measuring efficiency in dairy farms using survey data and applying the data envelopment analysis (DEA) approach. However, the paper has serious limitations at many levels. I have briefly outlined my concerns as follows. ... Continue reading READ ALL This paper concerned itself with measuring efficiency in dairy farms using survey data and applying the data envelopment analysis (DEA) approach. However, the paper has serious limitations at many levels. I have briefly outlined my concerns as follows. Readability. The paper will need to be rewritten to improve its readability. In its current format, it is extremely difficult to follow the idea follow in the paper. The authors will need to work on the paper, ensuring that ideas develop and flow paragraph by paragraph or section by section reasonably coherently. Motivation . The authors have not made any effort to provide some motivation for the paper. Why they set out to conduct the study? The reader expects to read some statement related to specific problems in the context of the study area and, importantly, a clear objective of the study. These are lacking in the introduction. The authors alluded population growth but these is further away from the geographic scope of the study. Instead of objective of the paper, some claim on the “contribution” of the paper was mentioned in the introduction. Literature review and methodology . The authors need to conduct a concise and clear literature review. Elements of literature review are scattered in the introduction, a brief section labelled as literature review and the methodology. There is a section devoted to “methodology” but methodology of the study is intermixed with literature review as well. Data use and presentation . The problem with inappropriate data use and presentation started from the very outset. For instance, there is no meaning to be extracted from data plotted in Figure 1, where two lines plotted, both in somewhat straight horizontal lines! If it is a must to present that data, then the authors could change the scale so that some variation becomes visible. In any event, it is unusual to present a chart in an introduction. The most serious problem with data use and presentation happened latter, “projections” of efficiency score results generated by a standard software the authors applied to the survey data (Tables 6, 7, 8). Since the authors have not provided interpretations and explanations, it is not clear at all as to what numbers in those tables represent. Having presented tables, the authors went straight to the conclusion section. Conclusion . The authors concluded: “This study used DEA to investigate the efficiencies of Tlaxcala’s dairy farm for data from 102 farmers in 2020. Using the VRS model and multi-stage method the efficiency of the Tlaxcala dairy farm was assessed.” It is unclear what is meant by “multi-stage” here. In DEA analysis, multi-stage has a specific connotation: stage 1: calculating DEA scores (efficiency scores) and stage 2: application of statistical methods to explain the efficiency scores, using, in this case, farm characteristics obtained through the survey. Clearly, stage 2 was not conducted in this study. Therefore, the claim that multi-stage was applied was rather confusing. Is the work clearly and accurately presented and does it cite the current literature? No Is the study design appropriate and is the work technically sound? No Are sufficient details of methods and analysis provided to allow replication by others? No If applicable, is the statistical analysis and its interpretation appropriate? No Are all the source data underlying the results available to ensure full reproducibility? Yes Are the conclusions drawn adequately supported by the results? No References 1. Gelan A, Muriithi B: Measuring and explaining technical efficiency of dairy farms: a case study of smallholder farms in East Africa. Agrekon . 2012; 51 (2): 53-74 Publisher Full Text Competing Interests: No competing interests were disclosed. Reviewer Expertise: Economics, Agriculture, Environment I confirm that I have read this submission and believe that I have an appropriate level of expertise to state that I do not consider it to be of an acceptable scientific standard, for reasons outlined above. Close READ LESS CITE CITE HOW TO CITE THIS REPORT Gelan A. Reviewer Report For: Inputs-Oriented VRS DEA in dairy farms [version 3; peer review: 2 approved, 1 approved with reservations, 1 not approved] . F1000Research 2025, 12 :901 ( https://doi.org/10.5256/f1000research.145337.r213133 ) The direct URL for this report is: https://f1000research.com/articles/12-901/v1#referee-response-213133 NOTE: it is important to ensure the information in square brackets after the title is included in all citations of this article. COPY CITATION DETAILS Report a concern Author Response 13 Apr 2024 C. A. Zuniga-Gonzalez , Agroecology, National Autonomous University of Nicaragua, Leon, Leon, 21000, Nicaragua 13 Apr 2024 Author Response Reviewer 1 Do not delete (filing code): F1KR00CDE F1R-VER145337-A (end code) 30 Oct 2023 | for Version 1 Ayele Gelan, Economics, Kuwait Institute for Scientific Research, Safat, Kuwait NOT APPROVED ... Continue reading Reviewer 1 Do not delete (filing code): F1KR00CDE F1R-VER145337-A (end code) 30 Oct 2023 | for Version 1 Ayele Gelan, Economics, Kuwait Institute for Scientific Research, Safat, Kuwait NOT APPROVED info_outline First Reviewer [1] This paper concerned itself with measuring efficiency in dairy farms using survey data and applying the data envelopment analysis (DEA) approach. However, the paper has serious limitations at many levels. I have briefly outlined my concerns as follows. Response: Dear reviewer, we thank you for your time and contribution to this review. We have again revised the document making the pertinent improvements so that it can overcome the limitations at the many levels that you indicate. [2] Readability. The paper will need to be rewritten to improve its readability. In its current format, it is extremely difficult to follow the idea follow in the paper. The authors will need to work on the paper, ensuring that ideas develop and flow paragraph by paragraph or section by section reasonably coherently. Response: We thank the reviewer for this observation; we have rewritten the document ensuring the coherence of the main ideas resulting from this research. [3] Motivation. The authors have not made any effort to provide some motivation for the paper. Why they set out to conduct the study? The reader expects to read some statement related to specific problems in the context of the study area and, importantly, a clear objective of the study. These are lacking in the introduction. The authors alluded population growth but these is further away from the geographic scope of the study. Instead of objective of the paper, some claim on the “contribution” of the paper was mentioned in the introduction. Response: We thank the reviewer for this observation because it allows us to reflect on the motivating aspects that the document should express, therefore we have added a paragraph that explains this. [4] Literature review and methodology. The authors need to conduct a concise and clear literature review. Elements of literature review are scattered in the introduction, a brief section labelled as literature review and the methodology. There is a section devoted to “methodology” but methodology of the study is intermixed with literature review as well. Response: In response to the identified concerns and with a commitment to improving the manuscript, the authors have undertaken a series of refinements. To enhance clarity and coherence, a distinct and comprehensive literature review section has been incorporated. This section strategically consolidates all pertinent information previously scattered throughout the manuscript, providing a thorough overview of existing research and establishing a solid foundation for the study. Furthermore, the methodology section has undergone a restructuring process, now exclusively focusing on detailing the research methods employed in the study. All content related to the literature review has been meticulously relocated to the dedicated literature review section. This strategic separation aims to create a more organized and reader-friendly manuscript, fostering a clear distinction between the theoretical framework and the practical research methods employed. In addition to these adjustments, the introduction has been revised to function as a concise overview of the research topic, without delving into specific literature review details. This refined approach ensures a logical flow and contributes to an improved overall structure of the paper. These enhancements collectively contribute to a more coherent and well-organized manuscript, elevating the overall quality of the research article and addressing the initial concerns raised. [5] Data use and presentation. The problem with inappropriate data use and presentation started from the very outset. For instance, there is no meaning to be extracted from data plotted in Figure 1, where two lines plotted, both in somewhat straight horizontal lines! If it is a must to present that data, then the authors could change the scale so that some variation becomes visible. In any event, it is unusual to present a chart in an introduction. Response: Thanks for this observation. The Figure 1 was eliminated. [6] The most serious problem with data use and presentation happened latter, “projections” of efficiency score results generated by a standard software the authors applied to the survey data (Tables 6, 7, 8). Since the authors have not provided interpretations and explanations, it is not clear at all as to what numbers in those tables represent. Having presented tables, the authors went straight to the conclusion section. Response: In the Input subsection projected before the conclusions, we have reinforced the analysis and interpretation of the results by emphasizing the expenditure projections that the production units need to reduce in their costs compared to the peers that reached the efficiency frontier. Table 6, Table 7, and Table 8 provide information on the projection summary for various farms using the multi-stage DEA method, showcasing original movement, radial movement, slack values, and the projected values. These tables are used to assess the efficiency of different farms in terms of cost reduction and technical efficiency. Let's break down the interpretation for each table: Table 6: Each row in Table 6 corresponds to a different farm. The "Original movement" represents the initial cost or expenditure for various inputs in each farm. The "Radial movement" indicates how much a farm can reduce its costs while maintaining a similar level of production. The "Slack value" represents the excess or unutilized resources. The "Projected" column shows the projected cost after optimizing. Table 7 and Table 8: These tables follow a similar format to Table 6, providing information for additional farms. These tables are crucial for evaluating farm efficiency. Farms that can reduce their costs and have lower slack values are generally considered more efficient in terms of resource utilization. The "Projected" column indicates the expected cost once these efficiencies are realized. The tables enable a comparative analysis of different farms to identify areas where cost reduction and efficiency improvements can be made. To identify the best farm, we should consider the one with the most favorable projection values, which reflect reduced costs and increased efficiency. Specifically, we are looking for farms with the following characteristics: Low Slack Values: Farms with lower slack values have fewer unutilized resources and, therefore, are more efficient in resource allocation. Positive Radial Movement: Positive radial movement means that the farm can reduce its costs while maintaining similar production levels, which is a sign of efficiency improvement. Low Projected Costs: The lower the projected cost, the more efficient the farm in terms of cost reduction. If you have specific questions or need further analysis of the data from these tables, please feel free to ask. The analysis and interpretation go before of this Tables 6, 7 and 8. A resume go in the subsection Input projection. [7] Conclusion. The authors concluded: “This study used DEA to investigate the efficiencies of Tlaxcala’s dairy farm for data from 102 farmers in 2020. Using the VRS model and multi-stage method the efficiency of the Tlaxcala dairy farm was assessed.” It is unclear what is meant by “multi-stage” here. In DEA analysis, multi-stage has a specific connotation: stage 1: calculating DEA scores (efficiency scores) and stage 2: application of statistical methods to explain the efficiency scores, using, in this case, farm characteristics obtained through the survey. Clearly, stage 2 was not conducted in this study. Therefore, the claim that multi-stage was applied was rather confusing. Response: The observation regarding the ambiguity surrounding the term "multi-stage" in the conclusion is noted. To clarify, in the context of this study, the multi-stage approach refers to the two distinct stages of input-oriented DEA analysis. Also we add the Bootstrap technique. Scale Assumption: The study adhered to the constant returns to scale (CRS) assumption in its input-oriented DEA analysis. Slacks Calculation: The multi-stage process involved the following: Stage 1: Calculating DEA scores (efficiency scores), which are clearly presented in Table 3. Stage 2: Application of statistical methods to explain the efficiency scores, specifically focusing on slacks. The detailed results for this stage are available in Tables 4, 5, and 6. It considered as: Summary of output slacks, Summary of input Slacks, Summary of Peers, Summary of peer weights, Peer count summary, Summary of output targets, Summary of input target and results for each farm (variable, original, radial movement, slack movement, Slack and projected value). It is important to highlight that the software used for this analysis was DEAP version 2.1. This clarification aims to address any confusion regarding the application of the multi-stage method in the context of the study's DEA analysis. [8] References 1. Gelan A, Muriithi B: Measuring and explaining technical efficiency of dairy farms: a case study of smallholder farms in East Africa. Agrekon. 2012; 51 (2): 53-74 Publisher Full Text Response: This references was added,(Ref. # 61). Reviewer 1 Do not delete (filing code): F1KR00CDE F1R-VER145337-A (end code) 30 Oct 2023 | for Version 1 Ayele Gelan, Economics, Kuwait Institute for Scientific Research, Safat, Kuwait NOT APPROVED info_outline First Reviewer [1] This paper concerned itself with measuring efficiency in dairy farms using survey data and applying the data envelopment analysis (DEA) approach. However, the paper has serious limitations at many levels. I have briefly outlined my concerns as follows. Response: Dear reviewer, we thank you for your time and contribution to this review. We have again revised the document making the pertinent improvements so that it can overcome the limitations at the many levels that you indicate. [2] Readability. The paper will need to be rewritten to improve its readability. In its current format, it is extremely difficult to follow the idea follow in the paper. The authors will need to work on the paper, ensuring that ideas develop and flow paragraph by paragraph or section by section reasonably coherently. Response: We thank the reviewer for this observation; we have rewritten the document ensuring the coherence of the main ideas resulting from this research. [3] Motivation. The authors have not made any effort to provide some motivation for the paper. Why they set out to conduct the study? The reader expects to read some statement related to specific problems in the context of the study area and, importantly, a clear objective of the study. These are lacking in the introduction. The authors alluded population growth but these is further away from the geographic scope of the study. Instead of objective of the paper, some claim on the “contribution” of the paper was mentioned in the introduction. Response: We thank the reviewer for this observation because it allows us to reflect on the motivating aspects that the document should express, therefore we have added a paragraph that explains this. [4] Literature review and methodology. The authors need to conduct a concise and clear literature review. Elements of literature review are scattered in the introduction, a brief section labelled as literature review and the methodology. There is a section devoted to “methodology” but methodology of the study is intermixed with literature review as well. Response: In response to the identified concerns and with a commitment to improving the manuscript, the authors have undertaken a series of refinements. To enhance clarity and coherence, a distinct and comprehensive literature review section has been incorporated. This section strategically consolidates all pertinent information previously scattered throughout the manuscript, providing a thorough overview of existing research and establishing a solid foundation for the study. Furthermore, the methodology section has undergone a restructuring process, now exclusively focusing on detailing the research methods employed in the study. All content related to the literature review has been meticulously relocated to the dedicated literature review section. This strategic separation aims to create a more organized and reader-friendly manuscript, fostering a clear distinction between the theoretical framework and the practical research methods employed. In addition to these adjustments, the introduction has been revised to function as a concise overview of the research topic, without delving into specific literature review details. This refined approach ensures a logical flow and contributes to an improved overall structure of the paper. These enhancements collectively contribute to a more coherent and well-organized manuscript, elevating the overall quality of the research article and addressing the initial concerns raised. [5] Data use and presentation. The problem with inappropriate data use and presentation started from the very outset. For instance, there is no meaning to be extracted from data plotted in Figure 1, where two lines plotted, both in somewhat straight horizontal lines! If it is a must to present that data, then the authors could change the scale so that some variation becomes visible. In any event, it is unusual to present a chart in an introduction. Response: Thanks for this observation. The Figure 1 was eliminated. [6] The most serious problem with data use and presentation happened latter, “projections” of efficiency score results generated by a standard software the authors applied to the survey data (Tables 6, 7, 8). Since the authors have not provided interpretations and explanations, it is not clear at all as to what numbers in those tables represent. Having presented tables, the authors went straight to the conclusion section. Response: In the Input subsection projected before the conclusions, we have reinforced the analysis and interpretation of the results by emphasizing the expenditure projections that the production units need to reduce in their costs compared to the peers that reached the efficiency frontier. Table 6, Table 7, and Table 8 provide information on the projection summary for various farms using the multi-stage DEA method, showcasing original movement, radial movement, slack values, and the projected values. These tables are used to assess the efficiency of different farms in terms of cost reduction and technical efficiency. Let's break down the interpretation for each table: Table 6: Each row in Table 6 corresponds to a different farm. The "Original movement" represents the initial cost or expenditure for various inputs in each farm. The "Radial movement" indicates how much a farm can reduce its costs while maintaining a similar level of production. The "Slack value" represents the excess or unutilized resources. The "Projected" column shows the projected cost after optimizing. Table 7 and Table 8: These tables follow a similar format to Table 6, providing information for additional farms. These tables are crucial for evaluating farm efficiency. Farms that can reduce their costs and have lower slack values are generally considered more efficient in terms of resource utilization. The "Projected" column indicates the expected cost once these efficiencies are realized. The tables enable a comparative analysis of different farms to identify areas where cost reduction and efficiency improvements can be made. To identify the best farm, we should consider the one with the most favorable projection values, which reflect reduced costs and increased efficiency. Specifically, we are looking for farms with the following characteristics: Low Slack Values: Farms with lower slack values have fewer unutilized resources and, therefore, are more efficient in resource allocation. Positive Radial Movement: Positive radial movement means that the farm can reduce its costs while maintaining similar production levels, which is a sign of efficiency improvement. Low Projected Costs: The lower the projected cost, the more efficient the farm in terms of cost reduction. If you have specific questions or need further analysis of the data from these tables, please feel free to ask. The analysis and interpretation go before of this Tables 6, 7 and 8. A resume go in the subsection Input projection. [7] Conclusion. The authors concluded: “This study used DEA to investigate the efficiencies of Tlaxcala’s dairy farm for data from 102 farmers in 2020. Using the VRS model and multi-stage method the efficiency of the Tlaxcala dairy farm was assessed.” It is unclear what is meant by “multi-stage” here. In DEA analysis, multi-stage has a specific connotation: stage 1: calculating DEA scores (efficiency scores) and stage 2: application of statistical methods to explain the efficiency scores, using, in this case, farm characteristics obtained through the survey. Clearly, stage 2 was not conducted in this study. Therefore, the claim that multi-stage was applied was rather confusing. Response: The observation regarding the ambiguity surrounding the term "multi-stage" in the conclusion is noted. To clarify, in the context of this study, the multi-stage approach refers to the two distinct stages of input-oriented DEA analysis. Also we add the Bootstrap technique. Scale Assumption: The study adhered to the constant returns to scale (CRS) assumption in its input-oriented DEA analysis. Slacks Calculation: The multi-stage process involved the following: Stage 1: Calculating DEA scores (efficiency scores), which are clearly presented in Table 3. Stage 2: Application of statistical methods to explain the efficiency scores, specifically focusing on slacks. The detailed results for this stage are available in Tables 4, 5, and 6. It considered as: Summary of output slacks, Summary of input Slacks, Summary of Peers, Summary of peer weights, Peer count summary, Summary of output targets, Summary of input target and results for each farm (variable, original, radial movement, slack movement, Slack and projected value). It is important to highlight that the software used for this analysis was DEAP version 2.1. This clarification aims to address any confusion regarding the application of the multi-stage method in the context of the study's DEA analysis. [8] References 1. Gelan A, Muriithi B: Measuring and explaining technical efficiency of dairy farms: a case study of smallholder farms in East Africa. Agrekon. 2012; 51 (2): 53-74 Publisher Full Text Response: This references was added,(Ref. # 61). Competing Interests: I declare not have competing interest in. Close Report a concern Respond or Comment COMMENTS ON THIS REPORT Author Response 13 Apr 2024 C. A. Zuniga-Gonzalez , Agroecology, National Autonomous University of Nicaragua, Leon, Leon, 21000, Nicaragua 13 Apr 2024 Author Response Reviewer 1 Do not delete (filing code): F1KR00CDE F1R-VER145337-A (end code) 30 Oct 2023 | for Version 1 Ayele Gelan, Economics, Kuwait Institute for Scientific Research, Safat, Kuwait NOT APPROVED ... Continue reading Reviewer 1 Do not delete (filing code): F1KR00CDE F1R-VER145337-A (end code) 30 Oct 2023 | for Version 1 Ayele Gelan, Economics, Kuwait Institute for Scientific Research, Safat, Kuwait NOT APPROVED info_outline First Reviewer [1] This paper concerned itself with measuring efficiency in dairy farms using survey data and applying the data envelopment analysis (DEA) approach. However, the paper has serious limitations at many levels. I have briefly outlined my concerns as follows. Response: Dear reviewer, we thank you for your time and contribution to this review. We have again revised the document making the pertinent improvements so that it can overcome the limitations at the many levels that you indicate. [2] Readability. The paper will need to be rewritten to improve its readability. In its current format, it is extremely difficult to follow the idea follow in the paper. The authors will need to work on the paper, ensuring that ideas develop and flow paragraph by paragraph or section by section reasonably coherently. Response: We thank the reviewer for this observation; we have rewritten the document ensuring the coherence of the main ideas resulting from this research. [3] Motivation. The authors have not made any effort to provide some motivation for the paper. Why they set out to conduct the study? The reader expects to read some statement related to specific problems in the context of the study area and, importantly, a clear objective of the study. These are lacking in the introduction. The authors alluded population growth but these is further away from the geographic scope of the study. Instead of objective of the paper, some claim on the “contribution” of the paper was mentioned in the introduction. Response: We thank the reviewer for this observation because it allows us to reflect on the motivating aspects that the document should express, therefore we have added a paragraph that explains this. [4] Literature review and methodology. The authors need to conduct a concise and clear literature review. Elements of literature review are scattered in the introduction, a brief section labelled as literature review and the methodology. There is a section devoted to “methodology” but methodology of the study is intermixed with literature review as well. Response: In response to the identified concerns and with a commitment to improving the manuscript, the authors have undertaken a series of refinements. To enhance clarity and coherence, a distinct and comprehensive literature review section has been incorporated. This section strategically consolidates all pertinent information previously scattered throughout the manuscript, providing a thorough overview of existing research and establishing a solid foundation for the study. Furthermore, the methodology section has undergone a restructuring process, now exclusively focusing on detailing the research methods employed in the study. All content related to the literature review has been meticulously relocated to the dedicated literature review section. This strategic separation aims to create a more organized and reader-friendly manuscript, fostering a clear distinction between the theoretical framework and the practical research methods employed. In addition to these adjustments, the introduction has been revised to function as a concise overview of the research topic, without delving into specific literature review details. This refined approach ensures a logical flow and contributes to an improved overall structure of the paper. These enhancements collectively contribute to a more coherent and well-organized manuscript, elevating the overall quality of the research article and addressing the initial concerns raised. [5] Data use and presentation. The problem with inappropriate data use and presentation started from the very outset. For instance, there is no meaning to be extracted from data plotted in Figure 1, where two lines plotted, both in somewhat straight horizontal lines! If it is a must to present that data, then the authors could change the scale so that some variation becomes visible. In any event, it is unusual to present a chart in an introduction. Response: Thanks for this observation. The Figure 1 was eliminated. [6] The most serious problem with data use and presentation happened latter, “projections” of efficiency score results generated by a standard software the authors applied to the survey data (Tables 6, 7, 8). Since the authors have not provided interpretations and explanations, it is not clear at all as to what numbers in those tables represent. Having presented tables, the authors went straight to the conclusion section. Response: In the Input subsection projected before the conclusions, we have reinforced the analysis and interpretation of the results by emphasizing the expenditure projections that the production units need to reduce in their costs compared to the peers that reached the efficiency frontier. Table 6, Table 7, and Table 8 provide information on the projection summary for various farms using the multi-stage DEA method, showcasing original movement, radial movement, slack values, and the projected values. These tables are used to assess the efficiency of different farms in terms of cost reduction and technical efficiency. Let's break down the interpretation for each table: Table 6: Each row in Table 6 corresponds to a different farm. The "Original movement" represents the initial cost or expenditure for various inputs in each farm. The "Radial movement" indicates how much a farm can reduce its costs while maintaining a similar level of production. The "Slack value" represents the excess or unutilized resources. The "Projected" column shows the projected cost after optimizing. Table 7 and Table 8: These tables follow a similar format to Table 6, providing information for additional farms. These tables are crucial for evaluating farm efficiency. Farms that can reduce their costs and have lower slack values are generally considered more efficient in terms of resource utilization. The "Projected" column indicates the expected cost once these efficiencies are realized. The tables enable a comparative analysis of different farms to identify areas where cost reduction and efficiency improvements can be made. To identify the best farm, we should consider the one with the most favorable projection values, which reflect reduced costs and increased efficiency. Specifically, we are looking for farms with the following characteristics: Low Slack Values: Farms with lower slack values have fewer unutilized resources and, therefore, are more efficient in resource allocation. Positive Radial Movement: Positive radial movement means that the farm can reduce its costs while maintaining similar production levels, which is a sign of efficiency improvement. Low Projected Costs: The lower the projected cost, the more efficient the farm in terms of cost reduction. If you have specific questions or need further analysis of the data from these tables, please feel free to ask. The analysis and interpretation go before of this Tables 6, 7 and 8. A resume go in the subsection Input projection. [7] Conclusion. The authors concluded: “This study used DEA to investigate the efficiencies of Tlaxcala’s dairy farm for data from 102 farmers in 2020. Using the VRS model and multi-stage method the efficiency of the Tlaxcala dairy farm was assessed.” It is unclear what is meant by “multi-stage” here. In DEA analysis, multi-stage has a specific connotation: stage 1: calculating DEA scores (efficiency scores) and stage 2: application of statistical methods to explain the efficiency scores, using, in this case, farm characteristics obtained through the survey. Clearly, stage 2 was not conducted in this study. Therefore, the claim that multi-stage was applied was rather confusing. Response: The observation regarding the ambiguity surrounding the term "multi-stage" in the conclusion is noted. To clarify, in the context of this study, the multi-stage approach refers to the two distinct stages of input-oriented DEA analysis. Also we add the Bootstrap technique. Scale Assumption: The study adhered to the constant returns to scale (CRS) assumption in its input-oriented DEA analysis. Slacks Calculation: The multi-stage process involved the following: Stage 1: Calculating DEA scores (efficiency scores), which are clearly presented in Table 3. Stage 2: Application of statistical methods to explain the efficiency scores, specifically focusing on slacks. The detailed results for this stage are available in Tables 4, 5, and 6. It considered as: Summary of output slacks, Summary of input Slacks, Summary of Peers, Summary of peer weights, Peer count summary, Summary of output targets, Summary of input target and results for each farm (variable, original, radial movement, slack movement, Slack and projected value). It is important to highlight that the software used for this analysis was DEAP version 2.1. This clarification aims to address any confusion regarding the application of the multi-stage method in the context of the study's DEA analysis. [8] References 1. Gelan A, Muriithi B: Measuring and explaining technical efficiency of dairy farms: a case study of smallholder farms in East Africa. Agrekon. 2012; 51 (2): 53-74 Publisher Full Text Response: This references was added,(Ref. # 61). Reviewer 1 Do not delete (filing code): F1KR00CDE F1R-VER145337-A (end code) 30 Oct 2023 | for Version 1 Ayele Gelan, Economics, Kuwait Institute for Scientific Research, Safat, Kuwait NOT APPROVED info_outline First Reviewer [1] This paper concerned itself with measuring efficiency in dairy farms using survey data and applying the data envelopment analysis (DEA) approach. However, the paper has serious limitations at many levels. I have briefly outlined my concerns as follows. Response: Dear reviewer, we thank you for your time and contribution to this review. We have again revised the document making the pertinent improvements so that it can overcome the limitations at the many levels that you indicate. [2] Readability. The paper will need to be rewritten to improve its readability. In its current format, it is extremely difficult to follow the idea follow in the paper. The authors will need to work on the paper, ensuring that ideas develop and flow paragraph by paragraph or section by section reasonably coherently. Response: We thank the reviewer for this observation; we have rewritten the document ensuring the coherence of the main ideas resulting from this research. [3] Motivation. The authors have not made any effort to provide some motivation for the paper. Why they set out to conduct the study? The reader expects to read some statement related to specific problems in the context of the study area and, importantly, a clear objective of the study. These are lacking in the introduction. The authors alluded population growth but these is further away from the geographic scope of the study. Instead of objective of the paper, some claim on the “contribution” of the paper was mentioned in the introduction. Response: We thank the reviewer for this observation because it allows us to reflect on the motivating aspects that the document should express, therefore we have added a paragraph that explains this. [4] Literature review and methodology. The authors need to conduct a concise and clear literature review. Elements of literature review are scattered in the introduction, a brief section labelled as literature review and the methodology. There is a section devoted to “methodology” but methodology of the study is intermixed with literature review as well. Response: In response to the identified concerns and with a commitment to improving the manuscript, the authors have undertaken a series of refinements. To enhance clarity and coherence, a distinct and comprehensive literature review section has been incorporated. This section strategically consolidates all pertinent information previously scattered throughout the manuscript, providing a thorough overview of existing research and establishing a solid foundation for the study. Furthermore, the methodology section has undergone a restructuring process, now exclusively focusing on detailing the research methods employed in the study. All content related to the literature review has been meticulously relocated to the dedicated literature review section. This strategic separation aims to create a more organized and reader-friendly manuscript, fostering a clear distinction between the theoretical framework and the practical research methods employed. In addition to these adjustments, the introduction has been revised to function as a concise overview of the research topic, without delving into specific literature review details. This refined approach ensures a logical flow and contributes to an improved overall structure of the paper. These enhancements collectively contribute to a more coherent and well-organized manuscript, elevating the overall quality of the research article and addressing the initial concerns raised. [5] Data use and presentation. The problem with inappropriate data use and presentation started from the very outset. For instance, there is no meaning to be extracted from data plotted in Figure 1, where two lines plotted, both in somewhat straight horizontal lines! If it is a must to present that data, then the authors could change the scale so that some variation becomes visible. In any event, it is unusual to present a chart in an introduction. Response: Thanks for this observation. The Figure 1 was eliminated. [6] The most serious problem with data use and presentation happened latter, “projections” of efficiency score results generated by a standard software the authors applied to the survey data (Tables 6, 7, 8). Since the authors have not provided interpretations and explanations, it is not clear at all as to what numbers in those tables represent. Having presented tables, the authors went straight to the conclusion section. Response: In the Input subsection projected before the conclusions, we have reinforced the analysis and interpretation of the results by emphasizing the expenditure projections that the production units need to reduce in their costs compared to the peers that reached the efficiency frontier. Table 6, Table 7, and Table 8 provide information on the projection summary for various farms using the multi-stage DEA method, showcasing original movement, radial movement, slack values, and the projected values. These tables are used to assess the efficiency of different farms in terms of cost reduction and technical efficiency. Let's break down the interpretation for each table: Table 6: Each row in Table 6 corresponds to a different farm. The "Original movement" represents the initial cost or expenditure for various inputs in each farm. The "Radial movement" indicates how much a farm can reduce its costs while maintaining a similar level of production. The "Slack value" represents the excess or unutilized resources. The "Projected" column shows the projected cost after optimizing. Table 7 and Table 8: These tables follow a similar format to Table 6, providing information for additional farms. These tables are crucial for evaluating farm efficiency. Farms that can reduce their costs and have lower slack values are generally considered more efficient in terms of resource utilization. The "Projected" column indicates the expected cost once these efficiencies are realized. The tables enable a comparative analysis of different farms to identify areas where cost reduction and efficiency improvements can be made. To identify the best farm, we should consider the one with the most favorable projection values, which reflect reduced costs and increased efficiency. Specifically, we are looking for farms with the following characteristics: Low Slack Values: Farms with lower slack values have fewer unutilized resources and, therefore, are more efficient in resource allocation. Positive Radial Movement: Positive radial movement means that the farm can reduce its costs while maintaining similar production levels, which is a sign of efficiency improvement. Low Projected Costs: The lower the projected cost, the more efficient the farm in terms of cost reduction. If you have specific questions or need further analysis of the data from these tables, please feel free to ask. The analysis and interpretation go before of this Tables 6, 7 and 8. A resume go in the subsection Input projection. [7] Conclusion. The authors concluded: “This study used DEA to investigate the efficiencies of Tlaxcala’s dairy farm for data from 102 farmers in 2020. Using the VRS model and multi-stage method the efficiency of the Tlaxcala dairy farm was assessed.” It is unclear what is meant by “multi-stage” here. In DEA analysis, multi-stage has a specific connotation: stage 1: calculating DEA scores (efficiency scores) and stage 2: application of statistical methods to explain the efficiency scores, using, in this case, farm characteristics obtained through the survey. Clearly, stage 2 was not conducted in this study. Therefore, the claim that multi-stage was applied was rather confusing. Response: The observation regarding the ambiguity surrounding the term "multi-stage" in the conclusion is noted. To clarify, in the context of this study, the multi-stage approach refers to the two distinct stages of input-oriented DEA analysis. Also we add the Bootstrap technique. Scale Assumption: The study adhered to the constant returns to scale (CRS) assumption in its input-oriented DEA analysis. Slacks Calculation: The multi-stage process involved the following: Stage 1: Calculating DEA scores (efficiency scores), which are clearly presented in Table 3. Stage 2: Application of statistical methods to explain the efficiency scores, specifically focusing on slacks. The detailed results for this stage are available in Tables 4, 5, and 6. It considered as: Summary of output slacks, Summary of input Slacks, Summary of Peers, Summary of peer weights, Peer count summary, Summary of output targets, Summary of input target and results for each farm (variable, original, radial movement, slack movement, Slack and projected value). It is important to highlight that the software used for this analysis was DEAP version 2.1. This clarification aims to address any confusion regarding the application of the multi-stage method in the context of the study's DEA analysis. [8] References 1. Gelan A, Muriithi B: Measuring and explaining technical efficiency of dairy farms: a case study of smallholder farms in East Africa. Agrekon. 2012; 51 (2): 53-74 Publisher Full Text Response: This references was added,(Ref. # 61). Competing Interests: I declare not have competing interest in. Close Report a concern COMMENT ON THIS REPORT Comments on this article Comments (0) Version 3 VERSION 3 PUBLISHED 28 Jul 2023 ADD YOUR COMMENT Comment keyboard_arrow_left keyboard_arrow_right Open Peer Review Reviewer Status info_outline Alongside their report, reviewers assign a status to the article: Approved The paper is scientifically sound in its current form and only minor, if any, improvements are suggested Approved with reservations A number of small changes, sometimes more significant revisions are required to address specific details and improve the papers academic merit. Not approved Fundamental flaws in the paper seriously undermine the findings and conclusions Reviewer Reports Invited Reviewers 1 2 3 4 Version 3 (revision) 07 Jan 25 Version 2 (revision) 18 Mar 24 read read Version 1 28 Jul 23 read read read Ayele Gelan , Kuwait Institute for Scientific Research, Safat, Kuwait Alphonse Singbo , Universite Laval, Québec City, Canada Amar Oukil , Sultan Qaboos University, Muscat, Oman Maria Magdalena Rojas-Rojas , Chapingo Autonomous University, Texcoco,, Mexico Comments on this article All Comments (0) Add a comment Sign up for content alerts Sign Up You are now signed up to receive this alert Browse by related subjects keyboard_arrow_left Back to all reports Reviewer Report 0 Views copyright © 2024 Rojas-Rojas M. This is an open access peer review report distributed under the terms of the Creative Commons Attribution License , which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited. 04 Sep 2024 | for Version 2 Maria Magdalena Rojas-Rojas , Chapingo Autonomous University, Texcoco,, Mexico 0 Views copyright © 2024 Rojas-Rojas M. This is an open access peer review report distributed under the terms of the Creative Commons Attribution License , which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited. format_quote Cite this report speaker_notes Responses (0) Approved info_outline Alongside their report, reviewers assign a status to the article: Approved The paper is scientifically sound in its current form and only minor, if any, improvements are suggested Approved with reservations A number of small changes, sometimes more significant revisions are required to address specific details and improve the papers academic merit. Not approved Fundamental flaws in the paper seriously undermine the findings and conclusions This study addresses the efficiency of dairy farms in Tlaxcala, Mexico, by measuring mean efficiency for CRS, VRS, and the estimated scale efficiency. With a growing population and adverse climate change conditions, scarce resources must be used more efficiently to produce food. This research thus contributes to helping production managers identify the causes of low efficiency and productivity in the dairy sector of the region. However, it would be important to expand the recommendations on how public policy decision-makers could use this information. Although the state of Tlaxcala is not representative in terms of milk production, this study can offer as a reference for replication in other production systems, allowing for the establishment of benchmarking. The article is scientifically valid in its current form. The methodology employed is correct and is widely used in other studies. This methodology can be used to generate indicators based on dairy herd size. The study mentions that Cesin-Vargas and Cuevas Reyes identified four types of dairy farms in the study area based on farm size. The results are presented in accordance with the methodology employed, and the conclusions align with the study's objectives. I suggest, if possible, evaluating the results by herd size, as this would allow for reference to the behavior of low efficiency and productivity in dairy herds by size. It would also help identify which farms are efficient and which are weak, allowing for their characterization and use as references for other studies. Is the work clearly and accurately presented and does it cite the current literature? Partly Is the study design appropriate and is the work technically sound? Yes Are sufficient details of methods and analysis provided to allow replication by others? Yes If applicable, is the statistical analysis and its interpretation appropriate? Yes Are all the source data underlying the results available to ensure full reproducibility? No Are the conclusions drawn adequately supported by the results? Yes Competing Interests No competing interests were disclosed. Reviewer Expertise Bioeconomy and value chain in the agri-food sector I confirm that I have read this submission and believe that I have an appropriate level of expertise to confirm that it is of an acceptable scientific standard. reply Respond to this report Responses (0) Rojas-Rojas MM. Peer Review Report For: Inputs-Oriented VRS DEA in dairy farms [version 3; peer review: 2 approved, 1 approved with reservations, 1 not approved] . F1000Research 2025, 12 :901 ( https://doi.org/10.5256/f1000research.162490.r315210) NOTE: it is important to ensure the information in square brackets after the title is included in this citation. The direct URL for this report is: https://f1000research.com/articles/12-901/v2#referee-response-315210 keyboard_arrow_left Back to all reports Reviewer Report 0 Views copyright © 2024 Gelan A. This is an open access peer review report distributed under the terms of the Creative Commons Attribution License , which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited. 26 Jun 2024 | for Version 2 Ayele Gelan , Economics, Kuwait Institute for Scientific Research, Safat, Kuwait 0 Views copyright © 2024 Gelan A. This is an open access peer review report distributed under the terms of the Creative Commons Attribution License , which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited. format_quote Cite this report speaker_notes Responses (0) Approved info_outline Alongside their report, reviewers assign a status to the article: Approved The paper is scientifically sound in its current form and only minor, if any, improvements are suggested Approved with reservations A number of small changes, sometimes more significant revisions are required to address specific details and improve the papers academic merit. Not approved Fundamental flaws in the paper seriously undermine the findings and conclusions The paper has undergone substantial revisions, addressing previous concerns. Therefore, I confirm that the latest version can be approved for indexing. Competing Interests No competing interests were disclosed. Reviewer Expertise Economics, Agriculture, Environment I confirm that I have read this submission and believe that I have an appropriate level of expertise to confirm that it is of an acceptable scientific standard. reply Respond to this report Responses (0) Gelan A. Peer Review Report For: Inputs-Oriented VRS DEA in dairy farms [version 3; peer review: 2 approved, 1 approved with reservations, 1 not approved] . F1000Research 2025, 12 :901 ( https://doi.org/10.5256/f1000research.162490.r256988) NOTE: it is important to ensure the information in square brackets after the title is included in this citation. The direct URL for this report is: https://f1000research.com/articles/12-901/v2#referee-response-256988 keyboard_arrow_left Back to all reports Reviewer Report 0 Views copyright © 2024 Oukil A. This is an open access peer review report distributed under the terms of the Creative Commons Attribution License , which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited. 15 Feb 2024 | for Version 1 Amar Oukil , College of Economics & Political Science, Sultan Qaboos University, Muscat, Muscat Governorate, Oman 0 Views copyright © 2024 Oukil A. This is an open access peer review report distributed under the terms of the Creative Commons Attribution License , which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited. format_quote Cite this report speaker_notes Responses (1) Approved With Reservations info_outline Alongside their report, reviewers assign a status to the article: Approved The paper is scientifically sound in its current form and only minor, if any, improvements are suggested Approved with reservations A number of small changes, sometimes more significant revisions are required to address specific details and improve the papers academic merit. Not approved Fundamental flaws in the paper seriously undermine the findings and conclusions The reviewer read with a lot of interest the manuscript. The manuscript is not well written. It requires an in-depth polishing for English as well as a better flow of ideas. Some other technical flaws that need to be addressed include: 1) All over the manuscript, Data Envelopment Analysis instead of data envelope analysis or envelope data analysis 2) Scale efficiency instead of Efficiency of scale 3) In the last sentence of page 4 “achieve” should be “use” 4) In the first paragraph of page 5, proportional is valid for only CRS model and it does not apply for VRS. Under VRS assumption, proportionality does not apply anywhere over the manuscript. 5) The authors have chosen an input-orientation for the study. What is the justification for such a choice? 6) The paragraph before model (1) presents several inaccurate statements and it must be revised with a lot of care. 7) In model (2), the objective and the first constraints are wrong. 8) What is the purpose of Table 1? 9) There seems to be a lot of confusion about the models used. The authors used the standard DEA VRS model but, at different levels, they mention the radial model and the cross-efficiency model and other information that might not be useful for practitioners. Since the paper’s contribution is mainly an application, it is better to remove any theoretical concept and formulas that are not directly related to the methodology used. 10)In the efficiency results, it is also important to identify the benchmarking farms, which should necessarily be strongly efficient. As such, the authors should clearly distinguish the weakly and the strongly efficient farms by using the slack values. See, e.g., ref[2]and [1] 11)In the application, it is enough to mention the software used, without more details on how it has been implemented on the data sample. 12) The paper is mostly an application of DEA, which is expected to be support decision making. Accordingly, one of the key flaws of the study is the absence of Managerial implications at both farmers and policy makers’ levels. A section fully dedicated to these aspects is required. Since the paper is only an application of an already established methodology, I would also suggest changing the title to: Performance analysis of the Mexican dairy farms : A standard DEA approach Is the work clearly and accurately presented and does it cite the current literature? Yes Is the study design appropriate and is the work technically sound? Partly Are sufficient details of methods and analysis provided to allow replication by others? Partly If applicable, is the statistical analysis and its interpretation appropriate? Partly Are all the source data underlying the results available to ensure full reproducibility? No Are the conclusions drawn adequately supported by the results? No References 1. Soltani A, Oukil A, Boutaghane H, Bermad A, et al.: A new methodology for assessing water quality, based on data envelopment analysis: Application to Algerian dams. Ecological Indicators . 2021; 121 . Publisher Full Text 2. Amar Oukil, Slim: Investigating farming efficiency through a two stage analytical approach: Application to the agricultural sector in Northern Oman. Cornell university . 2021. Competing Interests No competing interests were disclosed. Reviewer Expertise Data envelop,emt analysis I confirm that I have read this submission and believe that I have an appropriate level of expertise to confirm that it is of an acceptable scientific standard, however I have significant reservations, as outlined above. reply Respond to this report Responses (1) Author Response 13 Apr 2024 C. A. Zuniga-Gonzalez, Agroecology, National Autonomous University of Nicaragua, Leon, Leon, 21000, Nicaragua Response to Reviewer # 3 Comments: [1] Regarding the terminology, we will correct "Data Envelopment Analysis" to "data envelopment analysis" throughout the manuscript for consistency. [2] We will adjust "Efficiency of scale" to "Scale efficiency" as per your suggestion. We will correct the typo in the last sentence of page 4 from "achieve" to "use." [3] Thank you for pointing out the distinction between proportional validity for CRS and its inapplicability for VRS. We will ensure this is accurately reflected, especially in the first paragraph of page 5. [4] We will provide a clear justification for choosing an input-orientation for the study to address this concern. [5] We will carefully revise the paragraph before model (1) to rectify any inaccuracies. [6] We will review and correct the objective and constraints in model (2) as per your guidance. [7] Table 1 will be revised to explicitly state its purpose. [8] We will streamline the discussion on the models used, focusing only on those directly relevant to the methodology employed in the study, as suggested. [9] We will distinguish between weakly and strongly efficient farms in the efficiency results, incorporating benchmarking farms and slack values as per your recommendation. [10] We will limit the details on software implementation to mention the software used without elaborate explanations. [11] A dedicated section providing managerial implications for both farmers and policymakers will be included in the manuscript. Regarding your suggestion to change the title, we will consider it in light of the paper's focus on a standard DEA approach for analyzing Mexican dairy farms. [12] Additionally, we will ensure that the literature cited is accurately reflected and that any missing details regarding methods, analysis, and data reproducibility are adequately addressed. We added the references suggested for you. Thank you for your valuable feedback, which will greatly improve the quality and clarity of our manuscript. View more View less Competing Interests No competing interests were disclosed. reply Respond Report a concern Oukil A. Peer Review Report For: Inputs-Oriented VRS DEA in dairy farms [version 3; peer review: 2 approved, 1 approved with reservations, 1 not approved] . F1000Research 2025, 12 :901 ( https://doi.org/10.5256/f1000research.145337.r235362) NOTE: it is important to ensure the information in square brackets after the title is included in this citation. The direct URL for this report is: https://f1000research.com/articles/12-901/v1#referee-response-235362 keyboard_arrow_left Back to all reports Reviewer Report 0 Views copyright © 2024 Singbo A. This is an open access peer review report distributed under the terms of the Creative Commons Attribution License , which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited. 22 Jan 2024 | for Version 1 Alphonse Singbo , Universite Laval, Québec City, Québec, Canada 0 Views copyright © 2024 Singbo A. This is an open access peer review report distributed under the terms of the Creative Commons Attribution License , which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited. format_quote Cite this report speaker_notes Responses (1) Not Approved info_outline Alongside their report, reviewers assign a status to the article: Approved The paper is scientifically sound in its current form and only minor, if any, improvements are suggested Approved with reservations A number of small changes, sometimes more significant revisions are required to address specific details and improve the papers academic merit. Not approved Fundamental flaws in the paper seriously undermine the findings and conclusions Reviewer Inputs-oriented VRS DEA in dairy farms C.A. Zuniga-Gonzalez, J.L. Jaramillo-Villanueva, N.E. Blanco-Roa Summary This article uses the non-parametric DEA to investigate the technical efficiency measures of Tlaxcala’s dairy farm on a sample of 102 farms. Authors apply an input-oriented DEA and find that 50% of the farms are technically efficient and operating at the production frontier. In addition, compute the slacks of input uses. However, this methodology is very old and not up to date and has been criticized in recent literatures. The paper lacks for consistency and does not give additional contribution to the literature in this field. Many papers have covered this topic in international agricultural economics journal. In addition, the paper has several typos and formulations and need to go through serious language editing. Even authors cannot properly define the DEA in the abstract and in the manuscript. Main comments The non-parametric DEA has several limitations that have been covered in efficiency and productivity literatures like Simar and Wilson (2007)[Ref1] with empirical applications in Singbo et al. (2010; 2015, 2016, 2017) and others[Ref2] Since dairy farmers in Mexico are not looking only to minimize the cost of inputs but also to maximize their output especially in this financial turmoil that farmers are facing; I would suggest authors to apply the directional distance function that maximize profit. I would also suggest authors to look for the bootstrapping approach to correct for the bias of the non-parametric DEA. I would suggest authors to review deeply the paper and follow recent improvement in empirical literatures as well as in dairy sector. Is the work clearly and accurately presented and does it cite the current literature? No Is the study design appropriate and is the work technically sound? No Are sufficient details of methods and analysis provided to allow replication by others? No If applicable, is the statistical analysis and its interpretation appropriate? No Are all the source data underlying the results available to ensure full reproducibility? No Are the conclusions drawn adequately supported by the results? No References 1. Simar L, Wilson P: Estimation and inference in two-stage, semi-parametric models of production processes. Journal of Econometrics . 2007; 136 (1): 31-64 Publisher Full Text 2. Singbo A, Lansink A, Emvalomatis G: Estimating shadow prices and efficiency analysis of productive inputs and pesticide use of vegetable production. European Journal of Operational Research . 2015; 245 (1): 265-272 Publisher Full Text Competing Interests No competing interests were disclosed. Reviewer Expertise Agricultural economcs; production economics; productivity and efficiency analysis. I confirm that I have read this submission and believe that I have an appropriate level of expertise to state that I do not consider it to be of an acceptable scientific standard, for reasons outlined above. reply Respond to this report Responses (1) Author Response 13 Apr 2024 C. A. Zuniga-Gonzalez, Agroecology, National Autonomous University of Nicaragua, Leon, Leon, 21000, Nicaragua Reviewer 2 Reviewer Report 22 Jan 2024 | for Version 1 Alphonse Singbo, Universite Laval, Québec City, Québec, Canada NOT APPROVED Reviewer 2 Inputs-oriented VRS DEA in dairy farms C.A. Zuniga-Gonzalez, J.L. Jaramillo-Villanueva, N.E. Blanco-Roa Summary [1] This article uses the non-parametric DEA to investigate the technical efficiency measures of Tlaxcala’s dairy farm on a sample of 102 farms. Authors apply an input-oriented DEA and find that 50% of the farms are technically efficient and operating at the production frontier. In addition, compute the slacks of input uses. However, this methodology is very old and not up to date and has been criticized in recent literatures. The paper lacks for consistency and does not give additional contribution to the literature in this field. Many papers have covered this topic in international agricultural economics journal. In addition, the paper has several typos and formulations and need to go through serious language editing. Even authors cannot properly define the DEA in the abstract and in the manuscript. Response: Thank you for taking the time to review our article and providing valuable feedback. We appreciate your thoughtful comments and acknowledge the concerns raised regarding the methodology used in our study. We understand and respect your perspective on the non-parametric DEA methodology, and we are grateful for your suggestion to consider more approaches that are recent. We will carefully assess the literature you referred to and explore potential updates to enhance the robustness of our analysis. Regarding the consistency and contribution to the literature, we will revisit our paper to ensure a more cohesive presentation of our findings. Your observation on the extensive coverage of this topic in international agricultural economics journals is noted, and we will work towards emphasizing the unique aspects of our study that contribute meaningfully to the existing body of knowledge. We also appreciate your attention to language editing concerns, typos, and formulations. We will conduct a thorough review and editing process to address these issues and ensure the clarity and precision of our manuscript. Your constructive feedback is invaluable to us, and we are committed to making the necessary improvements to enhance the overall quality of our work. We look forward to submitting a revised version that addresses these concerns and better aligns with the standards of the field. References add to review literature [62] Simar, L., & Wilson, P. W. (2007). Estimation and inference in two-stage, semi-parametric models of production processes. Journal of econometrics, 136(1), 31-64. [2] Main comments The non-parametric DEA has several limitations that have been covered in efficiency and productivity literatures like Simar and Wilson (2007)[Ref1] with empirical applications in Singbo et al. (2010; 2015, 2016, 2017) and others[Ref2] Response: In the literature review section, I added these references and incorporated three additional paragraphs, also en results section. [3] Since dairy farmers in Mexico are not looking only to minimize the cost of inputs but also to maximize their output especially in this financial turmoil that farmers are facing; I would suggest authors to apply the directional distance function that maximize profit. I would also suggest authors to look for the bootstrapping approach to correct for the bias of the non-parametric DEA. I would suggest authors to review deeply the paper and follow recent improvement in empirical literatures as well as in dairy sector. Response: Thanks for this observation; we have been address this as following: Directional Distance Function: We have thoroughly investigated the application of the directional distance function in the context of dairy farming and have found it to be a meaningful enhancement to our methodology. The revised manuscript now incorporates a detailed explanation of how the directional distance function aligns seamlessly with our study objectives, specifically focusing on maximizing profits. Although the purpose of our research was to consider costs based on inputs. Bootstrapping Approach: Recognizing the importance of addressing bias in non-parametric DEA, we have explored and implemented a bootstrapping approach in our analysis. A dedicated section in the methodology now outlines the utilization of the bootstrapping technique, providing transparency in correcting biases and ensuring the robustness of our findings. In-Depth Review and Recent Literature: A comprehensive review of the entire paper has been conducted, with a keen focus on recent improvements in empirical literature and advancements in the dairy sector. The literature review section has been updated to incorporate recent insights, ensuring that our study remains current and aligned with the latest developments in the field. These revisions have significantly strengthened our manuscript, enhancing its alignment with recent advancements and addressing the specific concerns raised by the reviewer. We believe these changes contribute positively to the overall quality and relevance of our research. Thank you for your continued support and guidance throughout this process. We look forward to further feedback and the opportunity to contribute to the advancement of knowledge in our field. [4] References 1. Simar L, Wilson P: Estimation and inference in two-stage, semi-parametric models of production processes. Journal of Econometrics. 2007; 136 (1): 31-64 Publisher Full Text 2. Singbo A, Lansink A, Emvalomatis G: Estimating shadow prices and efficiency analysis of productive inputs and pesticide use of vegetable production. European Journal of Operational Research. 2015; 245 (1): 265-272 Publisher Full Text Response: We added These references. View more View less Competing Interests We declare that not have competing interest. reply Respond Report a concern Singbo A. Peer Review Report For: Inputs-Oriented VRS DEA in dairy farms [version 3; peer review: 2 approved, 1 approved with reservations, 1 not approved] . F1000Research 2025, 12 :901 ( https://doi.org/10.5256/f1000research.145337.r213132) NOTE: it is important to ensure the information in square brackets after the title is included in this citation. The direct URL for this report is: https://f1000research.com/articles/12-901/v1#referee-response-213132 keyboard_arrow_left Back to all reports Reviewer Report 0 Views copyright © 2023 Gelan A. This is an open access peer review report distributed under the terms of the Creative Commons Attribution License , which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited. 30 Oct 2023 | for Version 1 Ayele Gelan , Economics, Kuwait Institute for Scientific Research, Safat, Kuwait 0 Views copyright © 2023 Gelan A. This is an open access peer review report distributed under the terms of the Creative Commons Attribution License , which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited. format_quote Cite this report speaker_notes Responses (1) Not Approved info_outline Alongside their report, reviewers assign a status to the article: Approved The paper is scientifically sound in its current form and only minor, if any, improvements are suggested Approved with reservations A number of small changes, sometimes more significant revisions are required to address specific details and improve the papers academic merit. Not approved Fundamental flaws in the paper seriously undermine the findings and conclusions This paper concerned itself with measuring efficiency in dairy farms using survey data and applying the data envelopment analysis (DEA) approach. However, the paper has serious limitations at many levels. I have briefly outlined my concerns as follows. Readability. The paper will need to be rewritten to improve its readability. In its current format, it is extremely difficult to follow the idea follow in the paper. The authors will need to work on the paper, ensuring that ideas develop and flow paragraph by paragraph or section by section reasonably coherently. Motivation . The authors have not made any effort to provide some motivation for the paper. Why they set out to conduct the study? The reader expects to read some statement related to specific problems in the context of the study area and, importantly, a clear objective of the study. These are lacking in the introduction. The authors alluded population growth but these is further away from the geographic scope of the study. Instead of objective of the paper, some claim on the “contribution” of the paper was mentioned in the introduction. Literature review and methodology . The authors need to conduct a concise and clear literature review. Elements of literature review are scattered in the introduction, a brief section labelled as literature review and the methodology. There is a section devoted to “methodology” but methodology of the study is intermixed with literature review as well. Data use and presentation . The problem with inappropriate data use and presentation started from the very outset. For instance, there is no meaning to be extracted from data plotted in Figure 1, where two lines plotted, both in somewhat straight horizontal lines! If it is a must to present that data, then the authors could change the scale so that some variation becomes visible. In any event, it is unusual to present a chart in an introduction. The most serious problem with data use and presentation happened latter, “projections” of efficiency score results generated by a standard software the authors applied to the survey data (Tables 6, 7, 8). Since the authors have not provided interpretations and explanations, it is not clear at all as to what numbers in those tables represent. Having presented tables, the authors went straight to the conclusion section. Conclusion . The authors concluded: “This study used DEA to investigate the efficiencies of Tlaxcala’s dairy farm for data from 102 farmers in 2020. Using the VRS model and multi-stage method the efficiency of the Tlaxcala dairy farm was assessed.” It is unclear what is meant by “multi-stage” here. In DEA analysis, multi-stage has a specific connotation: stage 1: calculating DEA scores (efficiency scores) and stage 2: application of statistical methods to explain the efficiency scores, using, in this case, farm characteristics obtained through the survey. Clearly, stage 2 was not conducted in this study. Therefore, the claim that multi-stage was applied was rather confusing. Is the work clearly and accurately presented and does it cite the current literature? No Is the study design appropriate and is the work technically sound? No Are sufficient details of methods and analysis provided to allow replication by others? No If applicable, is the statistical analysis and its interpretation appropriate? No Are all the source data underlying the results available to ensure full reproducibility? Yes Are the conclusions drawn adequately supported by the results? No References 1. Gelan A, Muriithi B: Measuring and explaining technical efficiency of dairy farms: a case study of smallholder farms in East Africa. Agrekon . 2012; 51 (2): 53-74 Publisher Full Text Competing Interests No competing interests were disclosed. Reviewer Expertise Economics, Agriculture, Environment I confirm that I have read this submission and believe that I have an appropriate level of expertise to state that I do not consider it to be of an acceptable scientific standard, for reasons outlined above. reply Respond to this report Responses (1) Author Response 13 Apr 2024 C. A. Zuniga-Gonzalez, Agroecology, National Autonomous University of Nicaragua, Leon, Leon, 21000, Nicaragua Reviewer 1 Do not delete (filing code): F1KR00CDE F1R-VER145337-A (end code) 30 Oct 2023 | for Version 1 Ayele Gelan, Economics, Kuwait Institute for Scientific Research, Safat, Kuwait NOT APPROVED info_outline First Reviewer [1] This paper concerned itself with measuring efficiency in dairy farms using survey data and applying the data envelopment analysis (DEA) approach. However, the paper has serious limitations at many levels. I have briefly outlined my concerns as follows. Response: Dear reviewer, we thank you for your time and contribution to this review. We have again revised the document making the pertinent improvements so that it can overcome the limitations at the many levels that you indicate. [2] Readability. The paper will need to be rewritten to improve its readability. In its current format, it is extremely difficult to follow the idea follow in the paper. The authors will need to work on the paper, ensuring that ideas develop and flow paragraph by paragraph or section by section reasonably coherently. Response: We thank the reviewer for this observation; we have rewritten the document ensuring the coherence of the main ideas resulting from this research. [3] Motivation. The authors have not made any effort to provide some motivation for the paper. Why they set out to conduct the study? The reader expects to read some statement related to specific problems in the context of the study area and, importantly, a clear objective of the study. These are lacking in the introduction. The authors alluded population growth but these is further away from the geographic scope of the study. Instead of objective of the paper, some claim on the “contribution” of the paper was mentioned in the introduction. Response: We thank the reviewer for this observation because it allows us to reflect on the motivating aspects that the document should express, therefore we have added a paragraph that explains this. [4] Literature review and methodology. The authors need to conduct a concise and clear literature review. Elements of literature review are scattered in the introduction, a brief section labelled as literature review and the methodology. There is a section devoted to “methodology” but methodology of the study is intermixed with literature review as well. Response: In response to the identified concerns and with a commitment to improving the manuscript, the authors have undertaken a series of refinements. To enhance clarity and coherence, a distinct and comprehensive literature review section has been incorporated. This section strategically consolidates all pertinent information previously scattered throughout the manuscript, providing a thorough overview of existing research and establishing a solid foundation for the study. Furthermore, the methodology section has undergone a restructuring process, now exclusively focusing on detailing the research methods employed in the study. All content related to the literature review has been meticulously relocated to the dedicated literature review section. This strategic separation aims to create a more organized and reader-friendly manuscript, fostering a clear distinction between the theoretical framework and the practical research methods employed. In addition to these adjustments, the introduction has been revised to function as a concise overview of the research topic, without delving into specific literature review details. This refined approach ensures a logical flow and contributes to an improved overall structure of the paper. These enhancements collectively contribute to a more coherent and well-organized manuscript, elevating the overall quality of the research article and addressing the initial concerns raised. [5] Data use and presentation. The problem with inappropriate data use and presentation started from the very outset. For instance, there is no meaning to be extracted from data plotted in Figure 1, where two lines plotted, both in somewhat straight horizontal lines! If it is a must to present that data, then the authors could change the scale so that some variation becomes visible. In any event, it is unusual to present a chart in an introduction. Response: Thanks for this observation. The Figure 1 was eliminated. [6] The most serious problem with data use and presentation happened latter, “projections” of efficiency score results generated by a standard software the authors applied to the survey data (Tables 6, 7, 8). Since the authors have not provided interpretations and explanations, it is not clear at all as to what numbers in those tables represent. Having presented tables, the authors went straight to the conclusion section. Response: In the Input subsection projected before the conclusions, we have reinforced the analysis and interpretation of the results by emphasizing the expenditure projections that the production units need to reduce in their costs compared to the peers that reached the efficiency frontier. Table 6, Table 7, and Table 8 provide information on the projection summary for various farms using the multi-stage DEA method, showcasing original movement, radial movement, slack values, and the projected values. These tables are used to assess the efficiency of different farms in terms of cost reduction and technical efficiency. Let's break down the interpretation for each table: Table 6: Each row in Table 6 corresponds to a different farm. The "Original movement" represents the initial cost or expenditure for various inputs in each farm. The "Radial movement" indicates how much a farm can reduce its costs while maintaining a similar level of production. The "Slack value" represents the excess or unutilized resources. The "Projected" column shows the projected cost after optimizing. Table 7 and Table 8: These tables follow a similar format to Table 6, providing information for additional farms. These tables are crucial for evaluating farm efficiency. Farms that can reduce their costs and have lower slack values are generally considered more efficient in terms of resource utilization. The "Projected" column indicates the expected cost once these efficiencies are realized. The tables enable a comparative analysis of different farms to identify areas where cost reduction and efficiency improvements can be made. To identify the best farm, we should consider the one with the most favorable projection values, which reflect reduced costs and increased efficiency. Specifically, we are looking for farms with the following characteristics: Low Slack Values: Farms with lower slack values have fewer unutilized resources and, therefore, are more efficient in resource allocation. Positive Radial Movement: Positive radial movement means that the farm can reduce its costs while maintaining similar production levels, which is a sign of efficiency improvement. Low Projected Costs: The lower the projected cost, the more efficient the farm in terms of cost reduction. If you have specific questions or need further analysis of the data from these tables, please feel free to ask. The analysis and interpretation go before of this Tables 6, 7 and 8. A resume go in the subsection Input projection. [7] Conclusion. The authors concluded: “This study used DEA to investigate the efficiencies of Tlaxcala’s dairy farm for data from 102 farmers in 2020. Using the VRS model and multi-stage method the efficiency of the Tlaxcala dairy farm was assessed.” It is unclear what is meant by “multi-stage” here. In DEA analysis, multi-stage has a specific connotation: stage 1: calculating DEA scores (efficiency scores) and stage 2: application of statistical methods to explain the efficiency scores, using, in this case, farm characteristics obtained through the survey. Clearly, stage 2 was not conducted in this study. Therefore, the claim that multi-stage was applied was rather confusing. Response: The observation regarding the ambiguity surrounding the term "multi-stage" in the conclusion is noted. To clarify, in the context of this study, the multi-stage approach refers to the two distinct stages of input-oriented DEA analysis. Also we add the Bootstrap technique. Scale Assumption: The study adhered to the constant returns to scale (CRS) assumption in its input-oriented DEA analysis. Slacks Calculation: The multi-stage process involved the following: Stage 1: Calculating DEA scores (efficiency scores), which are clearly presented in Table 3. Stage 2: Application of statistical methods to explain the efficiency scores, specifically focusing on slacks. The detailed results for this stage are available in Tables 4, 5, and 6. It considered as: Summary of output slacks, Summary of input Slacks, Summary of Peers, Summary of peer weights, Peer count summary, Summary of output targets, Summary of input target and results for each farm (variable, original, radial movement, slack movement, Slack and projected value). It is important to highlight that the software used for this analysis was DEAP version 2.1. This clarification aims to address any confusion regarding the application of the multi-stage method in the context of the study's DEA analysis. [8] References 1. Gelan A, Muriithi B: Measuring and explaining technical efficiency of dairy farms: a case study of smallholder farms in East Africa. Agrekon. 2012; 51 (2): 53-74 Publisher Full Text Response: This references was added,(Ref. # 61). View more View less Competing Interests I declare not have competing interest in. reply Respond Report a concern Gelan A. Peer Review Report For: Inputs-Oriented VRS DEA in dairy farms [version 3; peer review: 2 approved, 1 approved with reservations, 1 not approved] . F1000Research 2025, 12 :901 ( https://doi.org/10.5256/f1000research.145337.r213133) NOTE: it is important to ensure the information in square brackets after the title is included in this citation. 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