Integrating Faculty Led Service Learning Training to Quantify Height of Natural Resources from a Spatial Science Perspective

Unger, Daniel; Kulhavy, David; Busch-Petersen, Kai; Hung, I‐Kuai

doi:10.5430/ijhe.v5n3p104

Cited by 10 publications

(12 citation statements)

References 19 publications

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“…Courses, students, and faculty within ATCOFA focus on hands-on instruction, field exercises, and real-world applications using the most current geospatial technology, most recently through the introduction of small Unmanned Aircraft Systems (UAS), or drones into forestry education to quantify natural resources (Unger, Kulhavy, Hung, & Zhang, 2014). To begin the use of UAS, students review the Mentored Undergraduate Scholarship (MUGS) rubric on use of UAS to gain confidence in understanding of UAS for teaching and research and service (Unger, Kulhavy, Busch-Petersen, & Hung, 2016). This promotes critical thinking, technical knowledge and skill, hands-on engagement, and construction of new concepts for use of UAS in education (Sattar, Tamatea, & Nawaz, 2017).…”

Section: Introductionmentioning

confidence: 99%

Integrating Unmanned Aircraft Systems to Measure Linear and Areal Features into Undergraduate Forestry Education

Viegut

Kulhavy

Unger

et al. 2018

IJHE

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The use of Unmanned Aircraft Systems (UAS) in undergraduate forestry education continues to expand and develop. Accuracy of data collection is an important aspect of preparation for “society-ready” foresters to meet the complex sustainable environment managing for ecological, social and economic interests. Hands-on use of a DJI Phantom 4 Pro UAS by undergraduates to measure the length and area of 30 linear features and areal features on Earth’s surface were estimated. These measurements were compared (measured within the ArcMap 10.5.2 interface) to hyperspectral Pictometry imagery measured on the web-based interface and the Google Earth Pro interface. Each remotely estimated measurement was verified with the actual ground measurements and the methods compared. An analysis of variance, conducted on the absolute length errors resulting in a p-value of 0.000057, concluded that the three length estimating techniques were statistically different at a 95% confidence interval. A Tukey pair-wise test found that the remotely sensed DJI Phantom 4 Pro data was statistically less accurate than the Pictometry and Google Earth Pro data, while both of which were found to be not different statistically in terms of accuracy. The areal feature area measurements were not normally distributed and therefore tested for equal medians using a Kruskal-Wallis test. The test found that there was no significant difference between sample medians, indicating that all three methods of estimating area are statistically equal in accuracy. The results indicate that Pictometry and Google Earth Pro could both be used to accurately estimate linear feature lengths remotely in lieu of in situ linear measurements while all three remote sensing techniques can be used to accurately estimate areal feature areas remotely in lieu of in situ areal measurements.

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Section: Introductionmentioning

confidence: 99%

Integrating Unmanned Aircraft Systems to Measure Linear and Areal Features into Undergraduate Forestry Education

Viegut

Kulhavy

Unger

et al. 2018

IJHE

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“…The use of a UAS to capture remotely sensed images at the user's discretion in natural resources add to the advantages in teaching and research (Unger, Kulhavy, Hung, Zhang & Stephens Williams, 2019). Students are trained in the safe use of UAS by a team of four geospatial science faculty members including safe operation, flying the UAS for individual images, video and orthophoto missions using a four-step training process of UAS assembly, completing a controlled flight, capturing imagery and videos, and synthesizing UAS information to quantify and qualify natural resource missions (Unger, Kulhavy, Busch-Petersen & Hung, 2016;Unger, Kulhavy, Hung, Zhang & Stephens Williams, 2019). Once students are trained, they complete a self-designed project with the supervision of one of the faculty members involving collecting and processing data.…”

Section: Accurate Height Measurementsmentioning

confidence: 99%

“…The accuracy of height estimates using a UAS, is an alternative depending on the internal GPS or/and internal barometer onboard a drone that is user controlled (Khanna et al, 2015;Themistocleous, 2014;Unger, Kulhavy, Busch-Petersen, & Hung, 2016). For accuracy with height measurements, landing the UAS DJI Phantom 3 between each flight increased the accuracy of the measurement even with the GPS turned off (Unger, Hung, Kulhavy, Zhang, & Busch-Petersen, 2018).…”

Section: Accurate Height Measurementsmentioning

confidence: 99%

Measuring Building Height Using Point Cloud Data Derived from Unmanned Aerial System Imagery in an Undergraduate Geospatial Science Course

Kulhavy¹,

Hung²,

Unger³

et al. 2021

HES

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The use of Unmanned Aerial Systems (UAS), also known as drones is increasing in geospatial science curricula within the United States. Within the Arthur Temple College of Forestry and Agriculture (ATCOFA) at Stephen F. Austin State University, Texas, seniors in the geospatial science program complete capstone projects to evaluate current geospatial technology to investigate complex ecological, social and environmental issues. Under the umbrella of a student initiated and designed senior project, students designed a study to estimate height of buildings with UAS data incorporating UAS data, LP360 and ArcScene programs, and Pictometry web-based interface. Results from a statistical analysis of the data confirm that geospatial science height estimation techniques can provide accurate estimates of height remotely. The independence of the students completing the project with UAS data for LP360 and ArcScene estimations, and utilizing Pictometry as an on-onscreen measuring tool, point to the need to integrate remote sensing, statistical analysis and synthesis of data into undergraduate geospatial science curricula. This reinforces the hands-on learning approach within ATCOFA and provides guidance to integrate the use of UAS in natural resource education.

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“…While traditional aerial photography from a manned airplane continues to serve projects of large areas, especially when acquiring aerial photography at a small scale, drone acquired imagery is suitable for smaller and inaccessible areas with the drone user controlling the spatial, spectral, radiometric, and temporal resolution of the product [6][7][8][9]. With limited capital investment, the process from setting up a drone flight to the output of a rectified orthomosaic image for a specific area can be achieved within hours [5,10], providing timely cost-effective monitoring of the forest environment [11,12]. Advantages of a UAS for mapping of small areas include high spatial resolution, the ability to complete time series imagery, potentials for 3D imagery to produce both orthomosaics and 3D models, and the integration into community-based forest monitoring (CBFM) or habitat monitoring [13].…”

Section: Introductionmentioning

confidence: 99%

Positional Precision Analysis of Orthomosaics Derived from Drone Captured Aerial Imagery

Hung

Unger

Kulhavy

2019

Drones

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The advancement of drones has revolutionized the production of aerial imagery. Using a drone with its associated flight control and image processing applications, a high resolution orthorectified mosaic from multiple individual aerial images can be produced within just a few hours. However, the positional precision and accuracy of any orthomosaic produced should not be overlooked. In this project, we flew a DJI Phantom drone once a month over a seven-month period over Oak Grove Cemetery in Nacogdoches, Texas, USA resulting in seven orthomosaics of the same location. We identified 30 ground control points (GCPs) based on permanent features in the cemetery and recorded the geographic coordinates of each GCP on each of the seven orthomosaics. Analyzing the cluster of each GCP containing seven coincident positions depicts the positional precision of the orthomosaics. Our analysis is an attempt to answer the fundamental question, “Are we obtaining the same geographic coordinates for the same feature found on every aerial image mosaic captured by a drone over time?” The results showed that the positional precision was higher at the center of the orthomosaic compared to the edge areas. In addition, the positional precision was lower parallel to the direction of the drone flight.

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Integrating Faculty Led Service Learning Training to Quantify Height of Natural Resources from a Spatial Science Perspective

Cited by 10 publications

References 19 publications

Integrating Unmanned Aircraft Systems to Measure Linear and Areal Features into Undergraduate Forestry Education

Integrating Unmanned Aircraft Systems to Measure Linear and Areal Features into Undergraduate Forestry Education

Measuring Building Height Using Point Cloud Data Derived from Unmanned Aerial System Imagery in an Undergraduate Geospatial Science Course

Positional Precision Analysis of Orthomosaics Derived from Drone Captured Aerial Imagery

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