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Publication Year: 2020 Subject: Social Sciences

21 to 30 of 84 Results

Replication Data for: Flood Hazard Modeling, Elevation May 4, 2020 - Measuring, Mapping, and Managing Flood Risk in Texas William Mobley, 2020, "Replication Data for: Flood Hazard Modeling, Elevation", https://doi.org/10.18738/T8/BPARY8, Texas Data Repository, V1 Elevation was calculated using the National Elevation Dataset (NED), which was provided as a seamless raster product via the LANDFIRE website at a 30-m resolution. For more information on the initial dataset see : https://www.landfire.gov/elevation.php
Replication Data for: Flood Hazard Modeling, Distance to Stream May 4, 2020 - Measuring, Mapping, and Managing Flood Risk in Texas William Mobley, 2020, "Replication Data for: Flood Hazard Modeling, Distance to Stream", https://doi.org/10.18738/T8/VLIS6E, Texas Data Repository, V1 Distance to Stream was calculated using Euclidean Distance based on the National Hydrography Dataset (NHD) stream and coastline features.
Replication Data for: Flood Hazard Modeling, Distance to Coast May 4, 2020 - Measuring, Mapping, and Managing Flood Risk in Texas William Mobley, 2020, "Replication Data for: Flood Hazard Modeling, Distance to Coast", https://doi.org/10.18738/T8/YYWO9P, Texas Data Repository, V1 Distance to coast were calculated using Euclidean Distance based on the National Hydrography Dataset (NHD) stream and coastline features.
Replication Data for: Flood Hazard Modeling, Average Roughness May 4, 2020 - Measuring, Mapping, and Managing Flood Risk in Texas William Mobley, 2020, "Replication Data for: Flood Hazard Modeling, Average Roughness", https://doi.org/10.18738/T8/5ZQMXV, Texas Data Repository, V1 Roughness values were assigned to each NLCD land cover class using the values suggested by Kalyanapu (2009), and, like KSAT, was averaged across the contributing upstream area for each raster cell for 2016. Kalyanapu, A.J., Burian, S.J. & McPherson, T.N., 2010. Effect of land use...
Replication Data for: Flood Hazard Modeling, Average Ksat May 4, 2020 - Measuring, Mapping, and Managing Flood Risk in Texas William Mobley, 2020, "Replication Data for: Flood Hazard Modeling, Average Ksat", https://doi.org/10.18738/T8/UKAGX0, Texas Data Repository, V1 KSAT values were assigned to soil classes obtained from the Natural Resources Conservation Service’s (NRCS) Soil Service Geographic Database (SSURGO) , and then averaged across the upstream area for each cell. (2020-04-28)
Replication data for: Effects of scale on multimodal deixis Sep 18, 2020 - Multimodal Deixis Mesh, Kate; Cruz, Emiliana; van de Weijer, Joost; Burnehult, Niclas; Gullberg, Marianne, 2020, "Replication data for: Effects of scale on multimodal deixis", https://doi.org/10.18738/T8/QHMQIY, Texas Data Repository, V2 Archived here are supplementary materials for the paper, Effects of scale on multimodal deixis. These include guidelines for video annotation, as well as datasets with gesture form coding from the study's first author (Kate Mesh) and reliability coder (Nicolas Femia). Statistical...
Replication Data for: Acoustic Differences Between Plain Coronals, Emphatic Coronals, and Primary Pharyngeals May 6, 2020 - Acoustic Differences Between Plain Coronals, Emphatic Coronals, and Primary Pharyngeals Faircloth, Laura, 2020, "Replication Data for: Acoustic Differences Between Plain Coronals, Emphatic Coronals, and Primary Pharyngeals", https://doi.org/10.18738/T8/PCQCP2, Texas Data Repository, V1 Soundfiles (.wav) and Praat TextGrids (.TextGrid) for this project. (This data is embargoed while awaiting publication and will be available at this DOI by May 2022)
Replication Data for Wu et al. (2020) "Multi-Modal Data Collection for Measuring Health, Behavior, and Living Environment of Large-Scale Participant Cohorts: Conceptual Framework and Findings from Deployments"(University of Texas at Austin) Nov 21, 2020University of Texas at Austin Dataverse Collection
Replication Data for The Weaponization of Web Archives: Data Craft and COVID-19 Publics Sep 23, 2020 - Amelia Acker Dataverse Acker, Amelia, 2020, "Replication Data for The Weaponization of Web Archives: Data Craft and COVID-19 Publics", https://doi.org/10.18738/T8/LUZATR, Texas Data Repository, V1 Web crawl provenance information.
Replication Data for Statistical Analysis Sep 15, 2020 - Replication data for: Pointing height marks target distance among the San Juan Quiahije Chatino. Mesh, Kate, 2020, "Replication Data for Statistical Analysis", https://doi.org/10.18738/T8/ZEUO8B, Texas Data Repository, V1 Included here is a dataset with gesture form coding from the study author (Kate Mesh). Statistical analysis of the dataset was performed using R version 3.6.1 (R Core Team, 2019), with the package, lmer (Bates, Maechler, Bolcher & Walker, 2015). An R script is attached for the pu...

Replication Data for: Flood Hazard Modeling, Elevation

May 4, 2020 - Measuring, Mapping, and Managing Flood Risk in Texas

William Mobley, 2020, "Replication Data for: Flood Hazard Modeling, Elevation", https://doi.org/10.18738/T8/BPARY8, Texas Data Repository, V1

Elevation was calculated using the National Elevation Dataset (NED), which was provided as a seamless raster product via the LANDFIRE website at a 30-m resolution. For more information on the initial dataset see : https://www.landfire.gov/elevation.php

Replication Data for: Flood Hazard Modeling, Distance to Stream

May 4, 2020 - Measuring, Mapping, and Managing Flood Risk in Texas

William Mobley, 2020, "Replication Data for: Flood Hazard Modeling, Distance to Stream", https://doi.org/10.18738/T8/VLIS6E, Texas Data Repository, V1

Distance to Stream was calculated using Euclidean Distance based on the National Hydrography Dataset (NHD) stream and coastline features.

Replication Data for: Flood Hazard Modeling, Distance to Coast

May 4, 2020 - Measuring, Mapping, and Managing Flood Risk in Texas

William Mobley, 2020, "Replication Data for: Flood Hazard Modeling, Distance to Coast", https://doi.org/10.18738/T8/YYWO9P, Texas Data Repository, V1

Distance to coast were calculated using Euclidean Distance based on the National Hydrography Dataset (NHD) stream and coastline features.

Replication Data for: Flood Hazard Modeling, Average Roughness

May 4, 2020 - Measuring, Mapping, and Managing Flood Risk in Texas

William Mobley, 2020, "Replication Data for: Flood Hazard Modeling, Average Roughness", https://doi.org/10.18738/T8/5ZQMXV, Texas Data Repository, V1

Roughness values were assigned to each NLCD land cover class using the values suggested by Kalyanapu (2009), and, like KSAT, was averaged across the contributing upstream area for each raster cell for 2016. Kalyanapu, A.J., Burian, S.J. & McPherson, T.N., 2010. Effect of land use...

Replication Data for: Flood Hazard Modeling, Average Ksat

May 4, 2020 - Measuring, Mapping, and Managing Flood Risk in Texas

William Mobley, 2020, "Replication Data for: Flood Hazard Modeling, Average Ksat", https://doi.org/10.18738/T8/UKAGX0, Texas Data Repository, V1

KSAT values were assigned to soil classes obtained from the Natural Resources Conservation Service’s (NRCS) Soil Service Geographic Database (SSURGO) , and then averaged across the upstream area for each cell. (2020-04-28)

Replication data for: Effects of scale on multimodal deixis

Sep 18, 2020 - Multimodal Deixis

Mesh, Kate; Cruz, Emiliana; van de Weijer, Joost; Burnehult, Niclas; Gullberg, Marianne, 2020, "Replication data for: Effects of scale on multimodal deixis", https://doi.org/10.18738/T8/QHMQIY, Texas Data Repository, V2

Archived here are supplementary materials for the paper, Effects of scale on multimodal deixis. These include guidelines for video annotation, as well as datasets with gesture form coding from the study's first author (Kate Mesh) and reliability coder (Nicolas Femia). Statistical...

Replication Data for: Acoustic Differences Between Plain Coronals, Emphatic Coronals, and Primary Pharyngeals

May 6, 2020 - Acoustic Differences Between Plain Coronals, Emphatic Coronals, and Primary Pharyngeals

Faircloth, Laura, 2020, "Replication Data for: Acoustic Differences Between Plain Coronals, Emphatic Coronals, and Primary Pharyngeals", https://doi.org/10.18738/T8/PCQCP2, Texas Data Repository, V1

Soundfiles (.wav) and Praat TextGrids (.TextGrid) for this project. (This data is embargoed while awaiting publication and will be available at this DOI by May 2022)

Replication Data for Wu et al. (2020) "Multi-Modal Data Collection for Measuring Health, Behavior, and Living Environment of Large-Scale Participant Cohorts: Conceptual Framework and Findings from Deployments"(University of Texas at Austin)

Nov 21, 2020University of Texas at Austin Dataverse Collection

Replication Data for The Weaponization of Web Archives: Data Craft and COVID-19 Publics

Sep 23, 2020 - Amelia Acker Dataverse

Acker, Amelia, 2020, "Replication Data for The Weaponization of Web Archives: Data Craft and COVID-19 Publics", https://doi.org/10.18738/T8/LUZATR, Texas Data Repository, V1

Web crawl provenance information.

Replication Data for Statistical Analysis

Sep 15, 2020 - Replication data for: Pointing height marks target distance among the San Juan Quiahije Chatino.

Mesh, Kate, 2020, "Replication Data for Statistical Analysis", https://doi.org/10.18738/T8/ZEUO8B, Texas Data Repository, V1

Included here is a dataset with gesture form coding from the study author (Kate Mesh). Statistical analysis of the dataset was performed using R version 3.6.1 (R Core Team, 2019), with the package, lmer (Bates, Maechler, Bolcher & Walker, 2015). An R script is attached for the pu...

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