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1. A 3-D Full-Wave Model to Study the Impact of Soybean Components and Structure on L-Band Backscatter

Author

Niknam, Kaiser, Judge, Jasmeet, Roberts, A. Kaleo, Monsivais-Huertero, Alejandro, Moore, Robert, Sarabandi, Kamal, and Wu, Jiayi

Subjects
Physics - Computational Physics, Electrical Engineering and Systems Science - Signal Processing
Abstract

Microwave remote sensing offers a powerful tool for monitoring the growth of short, dense vegetation like soybean. As the plants mature, changes in their biomass and 3-D structure impact the electromagnetic (EM) backscatter signal. This backscatter information holds valuable insights into crop health and yield, prompting the need for a comprehensive understanding of how structural and biophysical properties of soybeans as well as soil characteristics contribute to the overall backscatter signature. In this study, a full-wave model is developed for simulating L-band backscatter from soybean fields. Leveraging the ANSYS High-Frequency Structure Simulator (HFSS) framework, the model solves for the scattering of EM waves from realistic 3-D structural models of soybean, explicitly incorporating the interplant scattering effects. The model estimates of backscatter match well with the field observations from the SMAPVEX16-MicroWEX and SMAPVEX12, with average differences of 1-2 dB for co-pol and less than 4 dB for cross-pol. Furthermore, the model effectively replicates the temporal dynamics of crop backscatter throughout the growing season. The HFSS analysis revealed that the stems and pods are the primary contributors to HH-pol backscatter, while the branches contribute to VV-pol, and leaves impact the cross-pol signatures. In addition, a sensitivity study with 3-D bare soil surface resulted in an average variation of 8 dB in co- and cross-pol, even when the root mean square height and correlation length were held constant.

Published
2024

2. Gap-free 16-year (2005-2020) sub-diurnal surface meteorological observations across Florida

Author

Peeling, Julie, Judge, Jasmeet, Misra, Vasubandhu, Jayasankar, C. B., and Lusher, Rick

Subjects
Physics - Atmospheric and Oceanic Physics
Abstract

The rather unique sub-tropical, flat, peninsular region of Florida is subject to a unique climate with extreme weather events across the year that impacts agriculture, public health, and management of natural resources. Meteorological data at high temporal resolutions especially in the tropical latitudes are essential to understand diurnal and semi-diurnal variations of climate, which are considered to be the fundamental modes of climate variations of our Earth system. However, many meteorological datasets contain gaps that limit their use for validation of models and further detailed observational analysis. The objective of this paper is to apply a set of data gap filling strategies to develop a gap-free dataset with 15-minute observations for the sub-tropical region of Florida. Using data from the Florida Automated Weather Network (FAWN), methods of linear interpolation, trend continuation, reference to external sources, and nearest station substitution were applied to fill in the data gaps depending on the extent of the gap. The outcome of this study provides continuous, publicly accessible surface meteorological observations for 30 FAWN stations at 15-minute intervals for the years 2005-2020., Comment: 16 pages, 8 figures, 3 tables

Published
2023

4. Integrated Academic, Research, and Professional Experiences for 2-Year College Students Lowered Barriers in STEM Engagement: A Case Study in Geosciences

Author

Judge, Jasmeet, Lannon, Heidi J. L., Stofer, Kathryn A., Matyas, Corene J., Lanman, Brandon, Leissing, J. J., Rivera, Nicole, Norton, Heather, and Hom, Bobby

Abstract

Two-year community college (CC) students face many barriers for recruitment and retention into Science, Technology, Engineering, and Math (STEM) fields and vertical transfer to 4-year universities (4YUs). Experiential learning, mentoring, and cohort building are effective mechanisms for increasing STEM recruitment and retention, and close collaborations between CCs and 4YUs leverage complementary opportunities, supporting vertical transfer. We present a case study incorporating these concepts for a year-long Geoscience Education and Outreach Program (GEOP), a collaboration among a CC, a 4YU, and a non-profit science center, where 20 CC students participated in integrated academic, research, and internship components over three years. We present program design, implementation, revision, and outcomes for both students and institutions. Cohort-building activities encouraged professional conversations and built peer connections that addressed imposter syndrome, cultural divides, and other personal barriers to vertical transfer. The academic component had the highest completion rate, and a majority of respondents in exit interviews reported the internship as the most valuable experience, with half naming research or aspects thereof as most valuable. The vertical transfer exceeded typical CC rates, with 70% of GEOP students transferring to a 4YU, all in STEM disciplines. Successful implementation of GEOP required multi-institutional coordination, effective mentor-mentor and mentor-student communication, and program flexibility. Based upon our experiences, we provide several recommendations for implementation of similar programs.

Published
2022

5. In-Season Crop Progress in Unsurveyed Regions using Networks Trained on Synthetic Data

Author

Worrall, George and Judge, Jasmeet

Subjects
Computer Science - Machine Learning, Computer Science - Computer Vision and Pattern Recognition
Abstract

Many commodity crops have growth stages during which they are particularly vulnerable to stress-induced yield loss. In-season crop progress information is useful for quantifying crop risk, and satellite remote sensing (RS) can be used to track progress at regional scales. At present, all existing RS-based crop progress estimation (CPE) methods which target crop-specific stages rely on ground truth data for training/calibration. This reliance on ground survey data confines CPE methods to surveyed regions, limiting their utility. In this study, a new method is developed for conducting RS-based in-season CPE in unsurveyed regions by combining data from surveyed regions with synthetic crop progress data generated for an unsurveyed region. Corn-growing zones in Argentina were used as surrogate 'unsurveyed' regions. Existing weather generation, crop growth, and optical radiative transfer models were linked to produce synthetic weather, crop progress, and canopy reflectance data. A neural network (NN) method based upon bi-directional Long Short-Term Memory was trained separately on surveyed data, synthetic data, and two different combinations of surveyed and synthetic data. A stopping criterion was developed which uses the weighted divergence of surveyed and synthetic data validation loss. Net F1 scores across all crop progress stages increased by 8.7% when trained on a combination of surveyed region and synthetic data, and overall performance was only 21% lower than when the NN was trained on surveyed data and applied in the US Midwest. Performance gain from synthetic data was greatest in zones with dual planting windows, while the inclusion of surveyed region data from the US Midwest helped mitigate NN sensitivity to noise in NDVI data. Overall results suggest in-season CPE in other unsurveyed regions may be possible with increased quantity and variety of synthetic crop progress data.

Published
2022

6. PyLUSAT: An open-source Python toolkit for GIS-based land use suitability analysis

Author

Chen, Changjie, Judge, Jasmeet, and Hulse, David

Subjects
Computer Science - Computers and Society
Abstract

Desktop GIS applications, such as ArcGIS and QGIS, provide tools essential for conducting suitability analysis, an activity that is central in formulating a land-use plan. But, when it comes to building complicated land-use suitability models, these applications have several limitations, including operating system-dependence, lack of dedicated modules, insufficient reproducibility, and difficult, if not impossible, deployment on a computing cluster. To address the challenges, this paper introduces PyLUSAT: Python for Land Use Suitability Analysis Tools. PyLUSAT is an open-source software package that provides a series of tools (functions) to conduct various tasks in a suitability modeling workflow. These tools were evaluated against comparable tools in ArcMap 10.4 with respect to both accuracy and computational efficiency. Results showed that PyLUSAT functions were two to ten times more efficient depending on the job's complexity, while generating outputs with similar accuracy compared to the ArcMap tools. PyLUSAT also features extensibility and cross-platform compatibility. It has been used to develop fourteen QGIS Processing Algorithms and implemented on a high-performance computational cluster (HiPerGator at the University of Florida) to expedite the process of suitability analysis. All these properties make PyLUSAT a competitive alternative solution for urban planners/researchers to customize and automate suitability analysis as well as integrate the technique into a larger analytical framework.

Published
2021

8. Domain-guided Machine Learning for Remotely Sensed In-Season Crop Growth Estimation

Author

Worrall, George, Rangarajan, Anand, and Judge, Jasmeet

Subjects
Computer Science - Machine Learning, Computer Science - Computer Vision and Pattern Recognition
Abstract

Advanced machine learning techniques have been used in remote sensing (RS) applications such as crop mapping and yield prediction, but remain under-utilized for tracking crop progress. In this study, we demonstrate the use of agronomic knowledge of crop growth drivers in a Long Short-Term Memory-based, domain-guided neural network (DgNN) for in-season crop progress estimation. The DgNN uses a branched structure and attention to separate independent crop growth drivers and capture their varying importance throughout the growing season. The DgNN is implemented for corn, using RS data in Iowa for the period 2003-2019, with USDA crop progress reports used as ground truth. State-wide DgNN performance shows significant improvement over sequential and dense-only NN structures, and a widely-used Hidden Markov Model method. The DgNN had a 4.0% higher Nash-Sutfliffe efficiency over all growth stages and 39% more weeks with highest cosine similarity than the next best NN during test years. The DgNN and Sequential NN were more robust during periods of abnormal crop progress, though estimating the Silking-Grainfill transition was difficult for all methods. Finally, Uniform Manifold Approximation and Projection visualizations of layer activations showed how LSTM-based NNs separate crop growth time-series differently from a dense-only structure. Results from this study exhibit both the viability of NNs in crop growth stage estimation (CGSE) and the benefits of using domain knowledge. The DgNN methodology presented here can be extended to provide near-real time CGSE of other crops., Comment: 21 pages, 7 tables, 11 figures

Published
2021

10. Despite Challenges, 2-Year College Students Benefit from Faculty-Mentored Geoscience Research at a 4-Year University during an Extracurricular Program

Author

Matyas, Corene J., Stofer, Kathryn A., Lannon, Heidi J. L., Judge, Jasmeet, Hom, Bobby, and Lanman, Brandan A.

Abstract

This study details the mentored research component of a program intended to recruit, retain, and transfer students attending a two-year college (2YC) to four-year geosciences programs. Eighteen of 20 students who started the program were from minoritized backgrounds: 12 women, six racial/ethnic minorities, 12 low-income, and 13 first-generation college attendees. During a calendar year, students engaged in faculty-mentored research at a 4-year university (4YU), coursework at the 2YC, and a paid six-week internship in geoscience education. Students were to spend at least five hours weekly on research February-June and make a public presentation of results in December. Of 11 students who completed their research projects, 10 were minoritized students. Eight of 11 transferred into a science major. Students progressed the most in research when working together on a project designed for them and regularly meeting in-person with their mentors. Student exit interviews indicated that they valued the research experience and the skills gained. However, less progress occurred in the summer than planned, and students cited challenges in commuting to the 4YU due to jobs and personal commitments. Mentor-student matching produced mixed success. Based on the findings, we recommend incorporating a mini-internship with each mentor into the spring course, then pairing the students with one project and mentor for the summer and fall. Funding the research hours in addition to the internship would help alleviate financial burdens on students. Finally, all mentors would benefit from training together to better understand the mindsets of 2YC students and effectively accommodate individual needs.

Published
2022
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11. Two-Year College Students Report Multiple Benefits from Participation in an Integrated Geoscience Research, Coursework, and Outreach Internship Program

Author

Stofer, Kathryn A., Chandler, Jhenai W., Insalaco, Stephanie, Matyas, Corene, Lannon, Heidi J., Judge, Jasmeet, Lanman, Brandan, Hom, Bobby, and Norton, Heather

Abstract

Objective: Despite the availability of high-paying, high-demand careers, few women and students from underrepresented racial and ethnic minorities enter undergraduate programs understanding what the geosciences are and associated available career opportunities. This problem is compounded for students from backgrounds underrepresented in the United States. High-impact practices, such as mentoring, internships, undergraduate research experiences, and cohort-building, increase recruitment and retention of underrepresented students in science, technology, engineering, and math at 4-year institutions. What is not yet clear is the impact these interventions have on underrepresented students at two-year colleges, where the STEM pathway has become a main postsecondary school entry point for these students due to the affordability, flexibility, and academic support provided. Therefore, we designed, implemented, and researched a year-long program providing underrepresented students at a two-year college exposure to several of these experiences. Methods: We interviewed program participants about their perceptions and experiences in the program. Analysis proceeded using constant comparison. Results: Participants reported benefits from networking opportunities, gains in confidence, and gains in job skills, while some reported challenges for participation such as communication and time expectation conflicts; participants also struggled to balance the program with employment needs on top of school requirements. Different aspects of the program benefited different students, suggesting that all of these experiences could support recruitment and foster interest in geoscience for underrepresented students at two-year colleges. Conclusion: We conclude with implications for future research, program enhancements, and time constraint and mentoring needs related to characteristics of two-year college students.

Published
2021
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14. Spatial Scaling of Satellite Soil Moisture using Temporal Correlations and Ensemble Learning

Author

Chakrabarti, Subit, Judge, Jasmeet, Bongiovanni, Tara, Rangarajan, Anand, and Ranka, Sanjay

Subjects
Computer Science - Computer Vision and Pattern Recognition
Abstract

A novel algorithm is developed to downscale soil moisture (SM), obtained at satellite scales of 10-40 km by utilizing its temporal correlations to historical auxiliary data at finer scales. Including such correlations drastically reduces the size of the training set needed, accounts for time-lagged relationships, and enables downscaling even in the presence of short gaps in the auxiliary data. The algorithm is based upon bagged regression trees (BRT) and uses correlations between high-resolution remote sensing products and SM observations. The algorithm trains multiple regression trees and automatically chooses the trees that generate the best downscaled estimates. The algorithm was evaluated using a multi-scale synthetic dataset in north central Florida for two years, including two growing seasons of corn and one growing season of cotton per year. The time-averaged error across the region was found to be 0.01 $\mathrm{m}^3/\mathrm{m}^3$, with a standard deviation of 0.012 $\mathrm{m}^3/\mathrm{m}^3$ when 0.02% of the data were used for training in addition to temporal correlations from the past seven days, and all available data from the past year. The maximum spatially averaged errors obtained using this algorithm in downscaled SM were 0.005 $\mathrm{m}^3/\mathrm{m}^3$, for pixels with cotton land-cover. When land surface temperature~(LST) on the day of downscaling was not included in the algorithm to simulate "data gaps", the spatially averaged error increased minimally by 0.015 $\mathrm{m}^3/\mathrm{m}^3$ when LST is unavailable on the day of downscaling. The results indicate that the BRT-based algorithm provides high accuracy for downscaling SM using complex non-linear spatio-temporal correlations, under heterogeneous micro meteorological conditions.

Published
2016

15. Disaggregation of SMAP L3 Brightness Temperatures to 9km using Kernel Machines

Author

Chakrabarti, Subit, Bongiovanni, Tara, Judge, Jasmeet, Rangarajan, Anand, and Ranka, Sanjay

Subjects
Computer Science - Computer Vision and Pattern Recognition
Abstract

In this study, a machine learning algorithm is used for disaggregation of SMAP brightness temperatures (T$_{\textrm{B}}$) from 36km to 9km. It uses image segmentation to cluster the study region based on meteorological and land cover similarity, followed by a support vector machine based regression that computes the value of the disaggregated T$_{\textrm{B}}$ at all pixels. High resolution remote sensing products such as land surface temperature, normalized difference vegetation index, enhanced vegetation index, precipitation, soil texture, and land-cover were used for disaggregation. The algorithm was implemented in Iowa, United States, from April to July 2015, and compared with the SMAP L3_SM_AP T$_{\textrm{B}}$ product at 9km. It was found that the disaggregated T$_{\textrm{B}}$ were very similar to the SMAP-T$_{\textrm{B}}$ product, even for vegetated areas with a mean difference $\leq$ 5K. However, the standard deviation of the disaggregation was lower by 7K than that of the AP product. The probability density functions of the disaggregated T$_{\textrm{B}}$ were similar to the SMAP-T$_{\textrm{B}}$. The results indicate that this algorithm may be used for disaggregating T$_{\textrm{B}}$ using complex non-linear correlations on a grid., Comment: 14 Pages, 8 Figures, Submitted to IEEE Geoscience and Remote Sensing Letters

Published
2016

16. Downscaling Microwave Brightness Temperatures Using Self Regularized Regressive Models

Author

Chakrabarti, Subit, Judge, Jasmeet, Rangarajan, Anand, and Ranka, Sanjay

Subjects
Computer Science - Computer Vision and Pattern Recognition, 68
Abstract

A novel algorithm is proposed to downscale microwave brightness temperatures ($\mathrm{T_B}$), at scales of 10-40 km such as those from the Soil Moisture Active Passive mission to a resolution meaningful for hydrological and agricultural applications. This algorithm, called Self-Regularized Regressive Models (SRRM), uses auxiliary variables correlated to $\mathrm{T_B}$ along-with a limited set of \textit{in-situ} SM observations, which are converted to high resolution $\mathrm{T_B}$ observations using biophysical models. It includes an information-theoretic clustering step based on all auxiliary variables to identify areas of similarity, followed by a kernel regression step that produces downscaled $\mathrm{T_B}$. This was implemented on a multi-scale synthetic data-set over NC-Florida for one year. An RMSE of 5.76~K with standard deviation of 2.8~k was achieved during the vegetated season and an RMSE of 1.2~K with a standard deviation of 0.9~K during periods of no vegetation., Comment: 7 pages, 4 figures, submitted to be presented at the International Geoscience and Remote Sensing Conference 2015

Published
2015

17. Disaggregation of Remotely Sensed Soil Moisture in Heterogeneous Landscapes using Holistic Structure based Models

Author

Chakrabarti, Subit, Judge, Jasmeet, Rangarajan, Anand, and Ranka, Sanjay

Subjects
Computer Science - Computer Vision and Pattern Recognition, 68
Abstract

In this study, a novel machine learning algorithm is presented for disaggregation of satellite soil moisture (SM) based on self-regularized regressive models (SRRM) using high-resolution correlated information from auxiliary sources. It includes regularized clustering that assigns soft memberships to each pixel at fine-scale followed by a kernel regression that computes the value of the desired variable at all pixels. Coarse-scale remotely sensed SM were disaggregated from 10km to 1km using land cover, precipitation, land surface temperature, leaf area index, and in-situ observations of SM. This algorithm was evaluated using multi-scale synthetic observations in NC Florida for heterogeneous agricultural land covers. It was found that the root mean square error (RMSE) for 96% of the pixels was less than 0.02 $m^3/m^3$. The clusters generated represented the data well and reduced the RMSE by upto 40% during periods of high heterogeneity in land-cover and meteorological conditions. The Kullback Leibler divergence (KLD) between the true SM and the disaggregated estimates is close to 0, for both vegetated and baresoil landcovers. The disaggregated estimates were compared to those generated by the Principle of Relevant Information (PRI) method. The RMSE for the PRI disaggregated estimates is higher than the RMSE for the SRRM on each day of the season. The KLD of the disaggregated estimates generated by the SRRM is at least four orders of magnitude lower than those for the PRI disaggregated estimates, while the computational time needed was reduced by three times. The results indicate that the SRRM can be used for disaggregating SM with complex non-linear correlations on a grid with high accuracy., Comment: 28 pages, 14 figures, submitted to IEEE Transactions on Geoscience and Remote Sensing

Published
2015
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18. Evaluating Uncertainties in an SM-Based Inversion Algorithm for Irrigation Estimation in a Subtropical Humid Climate.

Author

Almendra-Martín, Laura, Judge, Jasmeet, Monsivaís-Huertero, Alejandro, and Liu, Pang-Wei

Subjects
SOIL depth, WATER management, ROOT-mean-squares, SOIL moisture, CORN farming
Abstract

Monitoring irrigation is crucial for sustainable water management in freshwater-limited regions. Even though soil moisture (SM)-based inversion algorithms have been widely used to estimate irrigation, scarcity of irrigation records has prevented a thorough understanding of their uncertainties, especially in humid regions. This study assesses the suitability of the SM2RAIN algorithm for estimating irrigation at field scale using high-temporal-resolution data from four corn growing experiments conducted in north-central Florida. Daily irrigation estimates were compared with observations, revealing root mean squared differences of 1.26 to 3.84 mm/day and Nash–Sutcliffe Efficiencies of 0.33 to 0.89. The estimates were more sensitive to uncertainties in static inputs of porosity, saturation moisture and soil thickness than they were to noise in time series inputs. Defining the saturation moisture as porosity made the algorithm insensitive to both parameters, while increasing soil thickness from 40 to 200 mm improved detection accuracies by 34–46%. In addition, the impact of SM on the estimations was investigated based on satellite overpass times. The analysis showed that morning passes produced more accurate estimates for the study site, while evening passes doubled the uncertainty. This study enhances the understanding of the SM2RAIN algorithm for irrigation estimation in subtropical humid conditions, guiding future high-resolution applications. [ABSTRACT FROM AUTHOR]

Published
2024
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25. Effects of high-quality elevation data and explanatory variables on the accuracy of flood inundation mapping via Height Above Nearest Drainage.

Author

Aristizabal, Fernando, Chegini, Taher, Petrochenkov, Gregory, Salas, Fernando, and Judge, Jasmeet

Subjects
OPTICAL radar, LIDAR, FLOOD risk, DIGITAL maps, ALTITUDES
Abstract

Given the availability of high-quality and high-spatial-resolution digital elevation maps (DEMs) from the United States Geological Survey's 3D Elevation Program (3DEP), derived mostly from light detection and ranging (lidar) sensors, we examined the effects of these DEMs at various spatial resolutions on the quality of flood inundation map (FIM) extents derived from a terrain index known as Height Above Nearest Drainage (HAND). We found that using these DEMs improved the quality of resulting FIM extents at around 80 % of the catchments analyzed when compared to using DEMs from the National Hydrography Dataset Plus High Resolution (NHDPlusHR) program. Additionally, we varied the spatial resolution of the 3DEP DEMs at 3, 5, 10, 15, and 20 m (meters), and the results showed no significant overall effect on FIM extent quality across resolutions. However, further analysis at coarser resolutions of 60 and 90 m revealed a significant degradation in FIM skill, highlighting the limitations of using extremely coarse-resolution DEMs. Our experiments demonstrated a significant burden in terms of the computational time required to produce HAND and related data at finer resolutions. We fit a multiple linear regression model to help explain catchment-scale variations in the four metrics employed and found that the lack of reservoir flooding or inundation upstream of river retention systems was a significant factor in our analysis. For validation, we used Interagency Flood Risk Management (InFRM) Base Level Engineering (BLE)-produced FIM extents and streamflows at the 100- and 500-year event magnitudes in a sub-region in eastern Texas. [ABSTRACT FROM AUTHOR]

Published
2024
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26. A Comparison of Passive Microwave Emission Models for Estimating Brightness Temperature at L- and P-Bands Under Bare and Vegetated Soil Conditions.

Author

Brakhasi, Foad, Walker, Jeffrey P., Judge, Jasmeet, Liu, Pang-Wei, Shen, Xiaoji, Ye, Nan, Wu, Xiaoling, Yeo, In-Young, Boopathi, Nithyapriya, Kim, Edward, Kerr, Yann H., and Jackson, Thomas J.

Abstract

P-band radiometry has been demonstrated to have a deeper sensing depth than L-band, making the consideration of multilayer microwave interactions necessary. In addition, the scattering and phase interference effects are different at the P-band, requiring a reconsideration of the need for coherent models. However, the impact remains to be clarified, and understanding the validity and limitations of these models at both L- and P-bands is crucial for their refinement and application. Therefore, two general categories of microwave emission models, including two stratified coherent models (Njoku and Wilhite) and four incoherent models (conventional tau-omega model and three multilayer models being zero-order, first-order, and incoherent solution), were intercompared for the first time on the same dataset. This evaluation utilized observations of L- and P-bands radiometry under different land cover conditions from a tower-based experiment in Victoria, Australia. Model estimations of brightness temperature (TB) were consistent with measurements, with the lowest root mean square error (RMSE) at P-band V-polarization under corn (2 K) and the highest RMSE at L-band H-polarization under bare soil (13 K). Coherent models performed slightly better than incoherent models under bare soil (3 K less RMSE), while the opposite was true under vegetated soil conditions (1 K less RMSE). Coherent and incoherent models showed maximum differences (3 K at P-band and 2 K at L-band), correlating strongly with soil moisture variations at 0–10 cm. Findings suggest that coherent and incoherent models performed similarly; thus, incoherent models may be preferable for estimating TB at L- and P-bands due to reduced computational complexity. [ABSTRACT FROM AUTHOR]

Published
2024
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27. Effects of High-Quality Elevation Data and Explanatory Variables on the Accuracy of Flood Inundation Mapping via Height Above Nearest Drainage

Author

Aristizabal, Fernando, Chegini, Taher, Petrochenkov, Gregory, Salas, Fernando Renzo, and Judge, Jasmeet

Abstract

Given the availability of high quality and high spatial resolution digital elevation models (DEMs) from the United States Geological Survey’s 3-Dimensional Elevation Program (3DEP) derived from mostly Light Detection and Ranging sensors, we examined the effects of these DEMs at various spatial resolutions on the quality of flood inundation map (FIM) extents derived from a terrain index known as Height Above Nearest Drainage (HAND). We found that using these DEMs improved the quality of resulting FIMs at around 80 % of the catchments analyzed when compared to using DEMs from the National Hydrography Dataset Plus High Resolution program. Additionally, we varied the spatial resolution of the 3DEP DEMs from 3, 5, 10, 15, and 20 meters and the results showed no significant overall effect on FIM extent quality across resolutions. However, our experiments demonstrated a significant burden on the computational time to produce HAND. We fit a multiple linear regression model to help explain catchment scale variation in the four metrics employed and found that the lack of reservoir flooding, or inundation upstream of river retention systems, was a significant factor in our analysis. For validation, we used Interagency Flood Risk Management Base Level Engineering produced FIM extents and streamflows at the 100 and 500 year event magnitudes in a sub-region in Eastern Texas.

Published
2023

31. Microwave Backscatter Phenomenology of Corn Fields at L-Band Using a Full-Wave Electromagnetic Solver

Author

Roberts, A. Kaleo, Wu, Jiayi, Monsivais-Huertero, Alejandro, Judge, Jasmeet, Moore, Robert C., and Sarabandi, Kamal

Abstract

Satellite and airborne radars currently monitor agricultural regions on Earth. Corn is a globally important crop that may benefit from radar observations for estimating soil moisture (SM) and other quantities. Estimates of SM could be used to enhance crop yield and aid in weather prediction. A scattering model is needed, however, to accurately estimate these quantities. Historically, corn is a difficult crop to model at microwave frequencies, and only approximate models for it exist. Novel models based on full-wave electromagnetic solvers can be more accurate by accounting for multiple scattering among plant constituents, other adjacent plants, and the underlying soil surface. Such a model is computationally expensive, but the increased availability of computing resources may make it more feasible. This article presents a model for corn at L-band based on finite element method (FEM) simulations in conjunction with Monte Carlo methods to estimate polarimetric backscattering coefficients. The FEM simulation uses periodic boundary conditions to limit its size. The physical representation of the corn plants comes from data-based 3-D plant models. The results of simulations are validated with synthetic aperture radar (SAR) data obtained during the SM active passive validation experiment of 2012 (SMAPVEX12) experimental campaign. The estimated backscattering coefficients of the SAR data are within ±2 dB for all polarization channels. Validation is performed for two days within the experimental campaign. Good agreement is observed between the simulated and measured values. This result indicates that the model can give novel insights into the scattering characteristics of corn. Future work remains to build an invertible model for estimating SM from backscatter measurements.

Published
2024
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40. Geoscience Engagement and Outreach (GEO) Public Page

Author

Lannon, Heidi, Stofer, Kathryn, Matyas, Corene, Judge, Jasmeet, Lanman, Brandan, Hom, Bobby, and Flynn, Jude

Subjects
geoscience, junior college, two-year college, undergraduate research, science outreach, community college, engagement
Abstract

GEO was a collaborative extracurricular project for Santa Fe College undergraduates with the University of Florida from 2016-2019. The goal of the project was to recruit and retain students from marginalized backgrounds into geoscience careers. This project presents supplemental materials and research and evaluation data. Funding from NSF ICER 1540724 1540729

Published
2022
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48. Towards Understanding the Influence of Vertical Water Distribution on Radar Backscatter from Vegetation Using a Multi-Layer Water Cloud Model

Author

Vermunt, P.C. (author), Steele-Dunne, S.C. (author), Khabbazan, S. (author), Kumar, V. (author), Judge, Jasmeet (author), Vermunt, P.C. (author), Steele-Dunne, S.C. (author), Khabbazan, S. (author), Kumar, V. (author), and Judge, Jasmeet (author)

Abstract

For a good interpretation of radar backscatter sensitivity to vegetation water dynamics, we need to know which parts of the vegetation layer control that backscatter. However, backscatter sensitivity to different depths in the canopy is poorly understood. This is partly caused by a lack of observational data to describe the vertical moisture distribution. In this study, we aimed to understand the sensitivity of L-band backscatter to water at different heights in a corn canopy. We studied changes in the contribution of different vertical layers to total backscatter throughout the season and during the day. Using detailed field measurements, we first determined the vertical distribution of moisture in the plants, and its seasonal and sub-daily variation. Then, these measurements were used to define different sublayers in a multi-layer water cloud model (WCM). To calibrate and validate the WCM, we used hyper-temporal tower-based polarimetric L-band scatterometer data. WCM simulations showed a shift in dominant scattering from the lowest 50 cm to 50–100 cm during the season in all polarizations, mainly due to leaf and ear growth and corresponding scattering and attenuation. Dew and rainfall interception raised sensitivity to upper parts of the canopy and lowered sensitivity to lower parts. The methodology and results presented in this study demonstrate the importance of the vertical moisture distribution on scattering from vegetation. These insights are essential to avoid misinterpretation and spurious artefacts during retrieval of soil moisture and vegetation parameters., Water Resources, Mathematical Geodesy and Positioning

Published
2022
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49. Extrapolating continuous vegetation water content to understand sub-daily backscatter variations

Author

Vermunt, P.C. (author), Steele-Dunne, S.C. (author), Khabbazan, S. (author), Judge, Jasmeet (author), van de Giesen, N.C. (author), Vermunt, P.C. (author), Steele-Dunne, S.C. (author), Khabbazan, S. (author), Judge, Jasmeet (author), and van de Giesen, N.C. (author)

Abstract

Microwave observations are sensitive to vegetation water content (VWC). Consequently, the increasing temporal and spatial resolution of spaceborne microwave observations creates a unique opportunity to study vegetation water dynamics and its role in the diurnal water cycle. However, we currently have a limited understanding of sub-daily variations in the VWC and how they affect microwave observations. This is partly due to the challenges associated with measuring internal VWC for validation, particularly non-destructively, and at timescales of less than a day. In this study, we aimed to (1) use field sensors to reconstruct diurnal and continuous records of internal VWC of corn and (2) use these records to interpret the sub-daily behaviour of a 10 d time series of polarimetric L-band backscatter with high temporal resolution. Sub-daily variations in internal VWC were calculated based on the cumulative difference between estimated transpiration and sap flow rates at the base of the stems. Destructive samples were used to constrain the estimates and for validation. The inclusion of continuous surface canopy water estimates (dew or interception) and surface soil moisture allowed us to attribute hour-to-hour backscatter dynamics either to internal VWC, surface canopy water, or soil moisture variations. Our results showed that internal VWC varied by 10 %–20 % during the day in non-stressed conditions, and the effect on backscatter was significant. Diurnal variations in internal VWC and nocturnal dew formation affected vertically polarized backscatter most. Moreover, multiple linear regression suggested that the diurnal cycle of VWC on a typical dry day leads to a 2 (HH, horizontally, and cross-polarized) to almost 4 (VV, vertically, polarized) times higher diurnal backscatter variation than the soil moisture drydown does. These results demonstrate that radar observations have the potential to provide unprecedented insight into the role of vegetation water dynamics in land, Water Resources, Mathematical Geodesy and Positioning

Published
2022
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50. In‐season crop phenology using remote sensing and model‐guided machine learning.

Author

Worrall, George, Judge, Jasmeet, Boote, Kenneth, and Rangarajan, Anand

Abstract

Accurate in‐season crop phenology estimation (CPE) using remote sensing (RS)‐based machine‐learning methods is challenging because of limited ground‐truth data. In this study, a biophysical crop model was used to guide neural network (NN)‐based, in‐season CPE. Using the Decision Support System for Agrotechnology Transfer (DSSAT), we conducted uncalibrated simulations for corn (Zea mays L.) across Iowa and Illinois in the U.S. Midwest with in‐season weather and historical information for planting and harvest. We investigated guiding the NN CPE method with growth stage (GSTD) and water stress factor (WSF) outputs from these simulations. Results show that guided NNs are able to estimate onset and progression of phenological stages more accurately than an unguided baseline and a crop model‐only method. GSTD guidance improved CPE during seasons when progress deviated from a regional average because of temperature but was detrimental during seasons of delayed planting and harvest. WSF guidance improved CPE during seasons when planting and harvest were delayed by heavy rainfall but performed less well during grainfill and mature stages. Neural network‐based CPE guided by both GSTD and WSF provided the most accurate estimates for pre‐emergence, emerged, silking, and grainfill stages as well as lower RMSE for the median stage transition date than reported in three full‐season CPE studies. An accurate RS method for estimating planting could link DSSAT simulations to the current planting window and improve upon these results. This model‐guided approach can be extended to other crops and regions to unlock in‐season crop risk assessments that are directly linked to crop phenology. Core Ideas: Remote sensing‐based CPE with machine learning is challenged by limited training data.DSSAT crop model outputs provide additional guidance to NN‐based CPE methods.An NN guided with GSTD and WSF from DSSAT outperforms unguided methods.GSTD improves CPE during seasons with abnormal temperatures; WSF improves CPE during rainfall‐driven delays.More accurate planting date estimates will improve crop model‐guided CPE during delayed seasons. [ABSTRACT FROM AUTHOR]

Published
2023
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