Spatial Eigenvector Predictive Mapping Using a Second Order Eigenfunction Eigen-decomposition Autocorrelation Specification in a Regional Convolution Neural Network in a Geo-Intelligent Smartphone App to Identify Lead Contamination in Primary and Secondar

Authors

  • Janessa Monchery Samuel P. Bell III College of Public Health, University of South Florida
  • Namit Choudhari School of Geosciences, College of Arts & Sciences, University of South Florida
  • Anusha Parajuli Department of Epidemiology, Samuel P. Bell III College of Public Health, University of South Florida
  • Aarya Satardekar Department of Health Policy and Systems Management, Samuel P. Bell III College of Public Health, University of South Florida
  • Caleb Jaramillo Global Communicable Diseases, Samuel P. Bell III College of Public Health, University of South Florida
  • Sasha Mosich Department of Epidemiology, Samuel P. Bell III College of Public Health, University of South Florida
  • Benjamin Jacob Department of Biostatistics and Data Science, Samuel P. Bell III College of Public Health, University of South Florida

DOI:

https://doi.org/10.14738/bjhr.1301.19722

Keywords:

Hot Spot, Eigen-decomposition Algorithm, R-CNN, ML, Geo-AI, iOS, Hillsborough County, Blood Lead Level, Lead Contamination

Abstract

Currently, there are no lead-contamination models to describe the locations of aggregation/non-aggregation sites (i.e., hot-and-cold spots) in Hillsborough County, Florida, USA. We generated a Global Moran's index (I) of spatial autocorrelation to identify hot-and-cold spots of lead contamination in Hillsborough County. The data used were based on lead sampling of water sources within the internal environments of elementary, middle, and high schools. A second-order eigenfunction eigen-decomposition algorithm embedded in a regional convolutional neural network (R-CNN) machine learning [ML] in a geo-spatial artificial intelligence [geo-AI] smartphone application yielded a model that identified Kingswood Elementary School as the most clustered geographic location with the highest lead contamination concentration levels. The spatial autocorrelation model also identified Essrig Elementary School as the least clustered geographic capture point. The Moran's I diagnostic summary plot revealed a final Z-score of 8.347 and a p-value of 0.000. Mapping hotspots of lead concentration using a second-order eigenfunction eigen-decomposition algorithm within an instantaneous R-CNN, ML, geo-AI, iOS pipeline can allow school administrative boards and policymakers to allocate resources to at-risk areas with lead contamination.

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Published

2026-01-18

How to Cite

Monchery, J., Choudhari, N., Parajuli, A., Satardekar, A., Jaramillo, C., Mosich, S., & Jacob, B. (2026). Spatial Eigenvector Predictive Mapping Using a Second Order Eigenfunction Eigen-decomposition Autocorrelation Specification in a Regional Convolution Neural Network in a Geo-Intelligent Smartphone App to Identify Lead Contamination in Primary and Secondar. British Journal of Healthcare and Medical Research, 13(01), 204–216. https://doi.org/10.14738/bjhr.1301.19722

Issue

Vol. 13 No. 01 (2026): British Journal of Healthcare and Medical Research

Section

Original Articles

License

Copyright (c) 2026 Janessa Monchery, Namit Choudhari, Anusha Parajuli, Aarya Satardekar, Caleb Jaramillo, Sasha Mosich, Benjamin Jacob

Creative Commons License

This work is licensed under a Creative Commons Attribution 4.0 International License.