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  <title><![CDATA[PhD Defense by Abigail R. Cohen]]></title>
  <body><![CDATA[<p>School of Civil and Environmental Engineering</p><p>Ph.D. Thesis Defense Announcement</p><p><strong>SEEDING NUTRIENT MANAGEMENT SUSTAINABILITY THROUGH DIGITAL AGRICULTURE</strong></p><p>By<strong>&nbsp;Abigail R. Cohen</strong></p><p>Advisor:</p><p><strong>Dr. Yongsheng Chen</strong></p><p>Committee Members:<strong>&nbsp; Dr. Xing Xie (CEE), Dr. Katherine Graham (CEE), Dr. Ameet Pinto (CEE), Dr. Rhuanito Soranz Ferrarezi (University of Georgia)</strong></p><p>Date and Time:<strong>&nbsp; August 12, 2025. 2:00 – 4:00 PM EST</strong></p><p>Location: <strong>ES&amp;T 3229, or on&nbsp;</strong><a href="https://gatech.zoom.us/j/91944860162?pwd=uoP8WKonbrkZs7InDcUSnxCbe6jfwg.1"><strong>Zoom</strong></a></p><p>ABSTRACT<br>Human activity dominates earth’s biogeochemical cycles, with agriculture<br>prevailing as one of the most consequential aggregate of processes on the planet.<br>As the basis for supporting life and all human activity, agriculture provides a critical<br>opportunity to mitigate some of these consequences through nutrient management<br>technology. While improvements to sensing, imaging, and computation can help<br>precision fertilization, phenotyping bottlenecks and a lack of unified modeling<br>approaches prevent scaling of precision nutrient management approaches. This<br>work provides a comprehensive critical review of technologies for nutrient<br>management in controlled environment agriculture (CEA), synthesizing literature<br>into a modular “system of compartments” framework called dynamically controlled<br>environment agriculture (DCEA).Recognizing bottlenecks and the need for modular, non-destructive nutrient<br>management models, we conducted a pilot-scale multimodal greenhouse<br>experiment using hyperspectral imaging (HSI) and multispectral imaging (MSI) to<br>expand DCEA. The experiment tested the limits of nutrient removal efficiency,<br>demonstrating significantly lower nutrient concentrations (50% of recommended)<br>could yield lettuce with over 75% fresh weight compared to the control, with healthy<br>tissue nitrogen concentrations. Next, the study provided a proof-of-concept using<br>Vision Transformer (ViT) deep learning (DL) architecture for regression analysis of<br>raw HSI data, bypassing the lengthy preprocessing pipelines typical of HSI-DL<br>approaches and facilitating end-to-end analysis.<br>Finally, a novel application of autoencoders (AE), a lightweight, adaptable DL<br>model, was deployed for anomalous growth detection using the in vivo MSI data.<br>Additionally, the study included an innovative energy use comparison of models<br>spanning the efficiency-accuracy spectrum (random forest and ViT), directly<br>addressing the environmental impacts of nutrient management automation and the<br>application of automation in resource-constrained edge environments. Results<br>revealed a 2% reduction in nitrogen application could completely offset the energy<br>use of the most complex DL model evaluated. Together, the work provides a<br>roadmap for resource-aware nutrient management modeling for precision<br>agriculture to facilitate environmentally sustainable food production.</p>]]></body>
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