Can we estimate farm size from field size? An empirical investigation of the field size to farm size relationship

IF 6.1 1区 农林科学 Q1 AGRICULTURE, MULTIDISCIPLINARY Agricultural Systems Pub Date : 2024-08-07 DOI:10.1016/j.agsy.2024.104088
Clemens Jänicke , Maximilian Wesemeyer , Cristina Chiarella , Tobia Lakes , Christian Levers , Patrick Meyfroidt , Daniel Müller , Marie Pratzer , Philippe Rufin
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Abstract

CONTEXT

Farm size is a key indicator associated with environmental, economic, and social contexts and outcomes of agriculture. Farm size data is typically obtained from agricultural censuses or household surveys, but both are usually only available in infrequent time intervals and at aggregate spatial scales. In contrast, spatially explicit and detailed data on individual fields can be accessed from cadastral information systems or agricultural subsidy applications in some regions or can be derived from Earth observation data. Empirically exploring the field-size-to-farm size relationship (FFR) is a lever to enhance our understanding of spatial patterns of farm sizes by assessing field sizes. However, our currently limited empirical knowledge does not allow for the characterization of the FFR over large spatial extents.

OBJECTIVE

We analyze the FFR using data from the Integrated Administration and Control System (IACS) for Germany. The IACS manages agricultural subsidy applications in the European Union; therefore, the data include spatial information on the extent of all fields and farms for which farmers have applied for subsidies.

METHODS

We developed a Bayesian multilevel model and a machine learning model to estimate farm size based on field size, controlling for contextual factors such as crop types, state boundaries, topography, and neighborhood effects.

RESULTS AND CONCLUSIONS

We found that farm size generally increased with field size for almost all federal states and crop type groups, but the FFR varied considerably in magnitude. Farm size predictions were accurate for medium-sized and large farms (50–7,000 ha, representing 66% of the data) with mean absolute percentage errors of 40–114%, but estimates for smaller farms had higher errors. To evaluate the relationship at the landscape level, we spatially aggregated the predictions into hexagons with a diameter of 15 km. This resulted in more accurate predictions (mean absolute percentage errors of 37%) than at the field level.

SIGNIFICANCE

Our study presents the first empirical insights into the FFR, opening future research directions towards producing spatially explicit farm size predictions at scale. Such information is key for monitoring scale transitions in agricultural systems, facilitating the design of timely and targeted interventions, and avoiding undesired outcomes of such processes.

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我们能根据田地面积估计农场规模吗?田地面积与农场规模关系的实证调查
农场规模是一个与农业的环境、经济和社会背景及结果相关的关键指标。农场规模数据通常来自农业普查或住户调查,但这两种数据通常只能在不太频繁的时间间隔和总体空间尺度上获得。与此相反,一些地区可以从地籍信息系统或农业补贴应用软件中获取单个田地的空间明确而详细的数据,也可以从地球观测数据中获取。通过对田地规模进行评估,实证探索田地规模与农场规模之间的关系(FFR)是增强我们对农场规模空间模式理解的一个杠杆。然而,我们目前有限的经验知识无法描述大空间范围内的 FFR 特征。我们利用德国综合行政与控制系统(IACS)的数据分析了FFR。IACS 管理欧盟的农业补贴申请;因此,数据包括农民申请补贴的所有田地和农场范围的空间信息。我们开发了一个贝叶斯多层次模型和一个机器学习模型,根据田地面积估算农场规模,同时控制作物类型、州界、地形和邻里效应等环境因素。我们发现,在几乎所有的联邦州和作物类型组中,农场规模一般随田地面积的增加而增加,但FFR 的大小差异很大。对中型和大型农场(50-7,000 公顷,占数据的 66%)的农场规模预测是准确的,平均绝对百分比误差为 40-114%,但对小型农场的估计误差较大。为了评估景观层面的关系,我们将预测结果在空间上汇总为直径为 15 千米的六边形。这样得出的预测结果(平均绝对百分比误差为 37%)比田间水平的预测结果更准确。我们的研究首次提出了对 FFR 的实证见解,为未来在规模上进行空间明确的农场规模预测开辟了研究方向。这些信息对于监测农业系统的规模转变、促进设计及时和有针对性的干预措施以及避免此类过程的不良后果至关重要。
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来源期刊
Agricultural Systems
Agricultural Systems 农林科学-农业综合
CiteScore
13.30
自引率
7.60%
发文量
174
审稿时长
30 days
期刊介绍: Agricultural Systems is an international journal that deals with interactions - among the components of agricultural systems, among hierarchical levels of agricultural systems, between agricultural and other land use systems, and between agricultural systems and their natural, social and economic environments. The scope includes the development and application of systems analysis methodologies in the following areas: Systems approaches in the sustainable intensification of agriculture; pathways for sustainable intensification; crop-livestock integration; farm-level resource allocation; quantification of benefits and trade-offs at farm to landscape levels; integrative, participatory and dynamic modelling approaches for qualitative and quantitative assessments of agricultural systems and decision making; The interactions between agricultural and non-agricultural landscapes; the multiple services of agricultural systems; food security and the environment; Global change and adaptation science; transformational adaptations as driven by changes in climate, policy, values and attitudes influencing the design of farming systems; Development and application of farming systems design tools and methods for impact, scenario and case study analysis; managing the complexities of dynamic agricultural systems; innovation systems and multi stakeholder arrangements that support or promote change and (or) inform policy decisions.
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