Understanding the limitations of grain yield monitor technology to inform on-farm research

IF 2 3区农林科学 Q2 AGRONOMY

Agronomy Journal Pub Date : 2024-09-21 DOI:10.1002/agj2.21695

Alysa Gauci, John Fulton, Scott Shearer, David J. Barker, Elizabeth Hawkins, Alexander J. Lindsey

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Abstract

Yield monitoring technology (YM) is a valuable tool to evaluate crop performance in on-farm research (OFR). However, limited information exists on utilizing this technology to accurately inform OFR. The objectives of this study were to evaluate the ability of grain yield monitor mass flow sensors to detect changes in corn (Zea mays L.) yield for different plot lengths, provide a recommended minimum plot length to utilize YM in OFR, and determine if differences in estimating yield existed between YMs. Six treatment lengths that varied in distance of intentional yield differences (7.6, 15.2, 30.5, 61.0, 121.9, and 243.8 m) were created by alternating high-yield (202 kg N/ha application) and low-yield (0 kg N/ha application) plots. A total of four grain YMs with impact-style mass flow sensors were used within two commercially available combines. Yield comparisons were made between the plot combine and YMs to evaluate the accuracy of each technology for detecting the magnitude of yield change across lengths using analysis of variance and exponential regression curves. Results indicated that the mass flow sensors were not sensitive enough to detect quickly changing flow rates for alternating yield changes in small plot lengths. Minimum plot lengths ranged from 43 to 107 m depending on YM. Significant differences were observed between grain YMs from different manufacturers. Future work could evaluate the influence additional crops or smaller yield differences have on the optimum OFR plot length.

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了解谷物产量监测技术的局限性，为农场研究提供依据

产量监测技术（YM）是评估农田研究（OFR）中作物表现的重要工具。然而，有关利用该技术为农田研究提供准确信息的资料却很有限。本研究的目的是评估谷物产量监测质量流量传感器检测不同地块长度的玉米（Zea mays L.）产量变化的能力，提供在农场研究中使用谷物产量监测技术的推荐最小地块长度，并确定不同谷物产量监测技术在估计产量方面是否存在差异。通过交替使用高产地块（每公顷施用 202 千克氮）和低产地块（每公顷施用 0 千克氮），创建了六种处理长度（7.6 米、15.2 米、30.5 米、61.0 米、121.9 米和 243.8 米），这些处理的有意产量差异距离各不相同。在两台市售联合收割机上共使用了四个装有冲击式质量流量传感器的谷物 YM。在小区联合收割机和 YM 之间进行了产量比较，以评估每种技术利用方差分析和指数回归曲线检测不同长度产量变化幅度的准确性。结果表明，质量流量传感器的灵敏度不够，无法检测到在小地块长度上产量交替变化的快速流量变化。根据不同的 YM，最小小区长度从 43 米到 107 米不等。不同制造商生产的谷物 YM 之间存在显著差异。未来的工作可以评估更多作物或更小的产量差异对最佳 OFR 小区长度的影响。

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来源期刊

Agronomy Journal 农林科学-农艺学

CiteScore

4.70

自引率

9.50%

发文量

265

审稿时长

4.8 months

期刊介绍： After critical review and approval by the editorial board, AJ publishes articles reporting research findings in soil–plant relationships; crop science; soil science; biometry; crop, soil, pasture, and range management; crop, forage, and pasture production and utilization; turfgrass; agroclimatology; agronomic models; integrated pest management; integrated agricultural systems; and various aspects of entomology, weed science, animal science, plant pathology, and agricultural economics as applied to production agriculture. Notes are published about apparatus, observations, and experimental techniques. Observations usually are limited to studies and reports of unrepeatable phenomena or other unique circumstances. Review and interpretation papers are also published, subject to standard review. Contributions to the Forum section deal with current agronomic issues and questions in brief, thought-provoking form. Such papers are reviewed by the editor in consultation with the editorial board.