index.html

<!doctype html> <html lang="en">
<!-- This is a generated file. Do not edit. -->
    <head>
        <meta charset="utf-8">
        <meta name="viewport" content="width=device-width, initial-scale=1.0, maximum-scale=1.0, user-scalable=no">

        <title>Austrian Academy of Sciences 2018 presentation</title>

        <meta name="description" content="Slides for Vienna 2018 presentation">
        <meta name="author" content="Helena Mitasova">

        <meta name="apple-mobile-web-app-capable" content="yes" />
        <meta name="apple-mobile-web-app-status-bar-style" content="black-translucent" />

        <meta name="viewport" content="width=device-width, initial-scale=1.0, maximum-scale=1.0, user-scalable=no">

        <link rel="stylesheet" href="css/reveal.css">
        <link rel="stylesheet" href="css/theme/ncsu-geoforall-lab.css" id="theme">
        <link rel="stylesheet" href="css/nouislider.css" id="slide">

        <!-- For syntax highlighting -->
        <link rel="stylesheet" href="lib/css/zenburn.css">
        <!-- For chalkboard plugin -->
        <link rel="stylesheet" href="https://maxcdn.bootstrapcdn.com/font-awesome/4.5.0/css/font-awesome.min.css">

        <!-- If the query includes 'print-pdf', include the PDF print sheet -->
        <!-- Printing and PDF exports -->
        <script>
            var link = document.createElement( 'link' );
            link.rel = 'stylesheet';
            link.type = 'text/css';
            link.href = window.location.search.match( /print-pdf/gi ) ? 'css/print/pdf.css' : 'css/print/paper.css';
            document.getElementsByTagName( 'head' )[0].appendChild( link );
        </script>

        <!--[if lt IE 9]>
        <script src="lib/js/html5shiv.js"></script>
        <![endif]-->
    </head>

    <body>

        <div class="reveal">

            <!-- Any section element inside of this container is displayed as a slide -->
            <div class="slides">
<section>
<!--<h4 style="color: #707070">AAS 2018</h4>-->
<h2 style="margin-top: 0.0em;color: #000"> 
Dynamic Surfaces <br> and Geospatial Processes </h2>
<p>
<h3 style="color: #707070">Helena Mitasova</h3>
<!--<img height="50px" style="margin-top: 2em" src="img/cgaBlack.png">
<h5 style="color: #000">North Carolina State University</h5>-->
<p>
<!--    <img src="img/hofierka.jpg" height="120">-->
    <img src="img/petrasova.jpg" height="120"> <img src="img/vpetras.jpg" height="120">
    <img src="img/baharmon.jpg" height="120"> <img src="img/payam.jpg" height="120">
    <img src="img/Justyna_Jeziorska.jpg" height="120">
</p>
<p><small>A. Petrasova, &nbsp; &nbsp; V. Petras, &nbsp; &nbsp; B. Harmon, 
&nbsp; &nbsp; P. Tabrizian, &nbsp; &nbsp; J. Jeziorska</small>
<p><img src="img/cgaBlack.png" height="40"> &nbsp; &nbsp; <img src="img/4x1white.jpg" height="25">
</section>

<section>
<h3>
An incomplete tour through evolution of surface modeling in open source GIS 
from its beginnings to current state and applications <h3>
<!--
<ul>
<h2>Dynamic Digital Earth is now a reality</h2>
Surface modeling  - helps to transform the digital earth data to support to improve disaster response, water and food security, everyday life and well being.
<li>Earth is mapped at many spatial and temporal scales from global by satellites to local microscale by drones
<li class="fragment">Only fraction of collected data is used to full potential
<li class="fragment">Geospatial analytics and modeling is deployed to use these data
</ul>
<p class="fragment">
<p class="fragment"><small><a href="https://earth.nullschool.net">Ocean Currents</a>2018 Cameron Beccario </small></p>
<aside class="notes">
https://www.nasa.gov/topics/earth/features/perpetual-ocean.html
https://svs.gsfc.nasa.gov/cgi-bin/details.cgi?aid=3827 - high res
http://hint.fm/wind/ realtime wind add to mea582 or gis714
</aside>
-->
</section>

<section>
<h2>The beginnings</h2>
</section>

<section>
<h3>Pioneering concept of dynamic spatial surfaces</h3>
<p>Waldo Tobler:
<p>geospatial phenomena as continuous scalar and vector fields
<p>
    <img height="330" src="img/surfaces/Tobler_pressuretomodesurface.jpg">
    <img height="330" src="img/surfaces/Tobler_govfiscal.jpg">
<p><small>Images from Professor Tobler's slides</small></p>
</section>

<section>
<h3>Theoretical foundations: terrain analysis</h3>
<p>Terrain as continuous field <i>z=f(x,y)</i>, 
<br>represented by isolines, manually deriving secondary fields
<p>
    <img src="img/surfaces/Krcho_krivosti.jpg" height="380">
<p> <small>Profle Curvature isolines (Krcho 1973), </small>
</section>

<section>
<h3>Computational foundations: digital terrain models</h3>
<p>EuroCarto III Graz, 1984: Krcho,J., H.Mitasova, E.Micietova, Theoretical concept and data structures of complex digital terrain model and its interdisciplinary applications 
<p>
    <img src="img/surfaces/TINgrassnviz2.jpg" height="170">
<br>    <img src="img/EurocartoGraz3.jpg" height="200">
    <img src="img/EurocartoGraz2.jpg" height="200">
<br><small>Thank you for supporting our participation 34 years ago</small>
</section>

<!-- <section>
<h3>Pioneering dynamic geospatial surfaces</h3>
<p> <img height="300" src="img/surfaces/Tobler_MapMachine.jpg">
    <img height="300" src="img/surfaces/Tobler_thankyou.jpg">
</section> -->

<section>
<h3>Digital terrain modeling with splines</h3>
<p>Regularized Spline with Tension (RST) interpolation: 
from scattered points to regular grids, with simultaneous
derivation of topographic parameters
<p>
    <img src="img/surfaces/curvature1993.jpg" height="400">
<br> <small>Profle Curvature draped over mesh surface, (Mitasova, Mitas, Hofierka 1993)</small>
</section>

<section>
<h3>Implementation in open source GRASS GIS</h3>
<p>Method became available to broad community,
many developers improved the code 
<p>Surface with changing tension animation: tension helps to control overshoots
<p><img class="stretch" src="img/surfaces/tension.gif">
<p><small>25 years: GRASS4.1 s.surf.tps, v.surf.tps, v.surf.rst; GRASS7.4; contributions of 8+ developers</small>
</section>

<section>
<h3>Implementation in open source GRASS GIS</h3>
<p>Quadtree-based segmentation made it applicable to large point data sets
<p>Simultaneous topographic analysis: slope, aspect, curvatures 
<p><img height="320" src="img/surfaces/quadtrees.png">
&nbsp; &nbsp;
&nbsp; &nbsp;
<img height="330" src="img/surfaces/topoanalysiscerl9803crop.gif">
</section>

<section>
<h2>Modeling and analysis of surfaces from multitemporal observations</h2>
</section>

<section>
<h3>From digitized contours to lidar point clouds</h3>
Lidar technology transformed topography mapping in 21st century
<p><img height="400" src="img/surfaces/digitized_cont2d_jr1999zoom.png">
<img height="400" src="img/surfaces/pointcloud2d_jr2009zoom.png">
<p>Do we still need interpolation?</p>
</section>

<section>
<h3>North Carolina lidar surveys</h3>
Coastal surveys started in 1996, second statewide survey just finished.
<br>Survey in 1999 included Jockey's Ridge dunes: dense, noisy scattered point cloud
<p><img height="440" src="img/surfaces/lidstorast1m.jpg">
<p><small>DEM: 1m resolution, binned</small>
</section>

<section>
<h3>North Carolina lidar surveys</h3>
Coastal surveys started in 1996, second statewide survey just finished.
<br>Survey in 1999 included Jockey's Ridge dunes: dense, noisy scattered point cloud
<p><img height="440" src="img/surfaces/lidstorast.jpg">
<p><small>DEM: 3m resolution, binned</small>
</section>

<section>
<h3>Regularized spline with tension for lidar</h3>
RST smoothing properties and quadtree segmentation
made it suitable for generating high resolution elevation models from millions of points
<p><img height="450" src="img/surfaces/liddfdm1e.jpg">
<p><small>DEM: 1m resolution, interpolated</small>
</section>

<section>
<h3>Regularized spline with tension for lidar</h3>
By tuning the tension coupled with smoothing, we remove noise and derive topographic parameters at a desired level of detail:
<br>profile curvature and slope draped over surface with changing tension
<p><img class="stretch" src="img/surfaces/lidar_tension_curv.gif">
</section>

<!--
<section>
    <h3>DEM feature extraction</h3>
<p> Dune crests were extracted from profile curvatures of DEMs spanning 44 years 
<br>to quantify dune migration rates and direction
<p>
<img height="350" src="img/surfaces/rfpfig4pcurv.jpg"> 
<img height="350" src="img/surfaces/rfpfig4crestevol.jpg"> 
ADD GRAPHS linear loss of elevation since 1953, accelerating migration 3-6 m/yr, 
</section>
-->
<section>
<h3>GRASS temporal framework for DEM time series</h3>
DEM time series for Jockey's Ridge dunes derived from data acquired by 
<ul>
  <li>photogrammetry (1974-98), 
  <li>lidar (1999-2015), 
  <li>structure from motion from UAS imagery (2016-2017)
</ul>
  <img height="100" src="img/surfaces/timeline.png"> 
   <img height="150" src="img/surfaces/timeline3D.png"> 
<br>
   <img height="130" src="img/surfaces/temp_plot_leeward_pt.png"> 
   <img height="130" src="img/surfaces/temp_plot_windward_pt.png"> 
<br><small>Gebbert, S., Pebesma, E., 2014. A temporal GIS for field based environmental modeling. Environmental Modelling and Software 53, 1-12.</small>
</section>

<section>
    <h3>DEM time series visualization</h3>
<p>Jockey's Ridge 1974 - 2017: southward migration, landform transformation
from crescentic dune to sand starved, fast moving parabolic dune
<!--    <img height="350" src="img/surfaces/jrseries.png"> -->
    <img class="stretch" src="img/surfaces/jr_74_17_anim3dlgfix.gif">
</section>


<section class="stretch" data-animate="1,13" data-path="img/surfaces/JR_anim/JR_anim">
<h3>DEM time series visualization 1997 - 2017</h3>

</section>

<section>
    <h3>Contours time series</h3>
Contours capture the landform change but they are hard to read
<br>   <img height="260" src="img/surfaces/jr_74_2017_16mcontour.png"> 16m
<br>   <img height="230" src="img/surfaces/jr_74_2017_20mcontour.jpg"> 20m
<!--   <img height="130" src="img/surfaces/jr16/legend.png"> -->
</section>

<section >
    <h3>Space-Time cube visualization</h3>
<p>DEM time series is converted into space-time voxel model in TGRASS and evolution of a contour 
is represented as isosurface: 16m and 20m </p>
  <img height="400" src="img/surfaces/jr16/animation.gif"> 
<!--<img src="img/jr18/animation.gif"> -->
<img height="400" src="img/surfaces/jr20/animation.gif"> 
</section>

<section>
<h3>Jockey's Ridge evolution analysis</h3>
<p>DEM time series: evolution quantified using TGRASS and surface analysis tools 
<ul>
  <li>linear trend in loss of peak elevation at 0.3m per year 
  <li>accelerating horizontal migration from 3m/yr to 6m/yr
  <li>total sand volume is stable, but the <strong>core</strong> (sand that has not moved) is shrinking
<!--  <li>vegetation increased, but dune still kills trees on the leeward side-->
  <li>management challenges: dynamic feature confined to static park boundaries
</ul>
<p>
<!--<img height="150" src="img/surfaces/core_2017_cut6.jpg">-->
<img height="200" src="img/surfaces/jr_74_17_cut3.jpg">
<img height="200" src="img/surfaces/peakregression_1950_2017.png">
</section>

<!--
<section>
<h3>Jockey's Ridge story</h3>
<p>The 43 m high dune was a transient landform 
<p><img height="200" src="img/surfaces/JR_photosevol_17_50_08.jpg">
<br>
<img height="220" src="img/surfaces/Kittytrees1900.jpg">
<img height="220" src="img/surfaces/JR_2017_burriedtrees.jpg">
<p><small>Dune in early 1900 and in 2008, 2016</small>
</section>
-->

<section>
<h2>From observations to modeling of processes</h2>
</section>


<section>
<h3>Water flow, soil erosion, storm surge</h3>
<p>Land surface controls water and sediment flow across landscapes
<p>Critical processes and impacts: surface runoff, flooding, storm surge, soil erosion
<p><img height="220" src="img/surfaces/secrefstorm2006Alberto.jpg">
<img height="220" src="img/surfaces/secref8-8-03ditch.jpg">
<img height="220" src="img/surfaces/IreneRodanthe.jpg">
</section>

<section>
<h3>Water flow</h3>
<p>Using surface gradients to compute flow accumulation:
Evolution of water depth over complex terrain
under steady rainfall and uniform surface conditions
<p>
<img height="350" src="img/surfaces/water.gif">
<p>Geometry-based solution
</section>

<section>
<h3>Sediment transport</h3>
<p>Combining flow accumulation and slope: 
<br>Evolution of sediment transport capacity
<p>
<img height="350" src="img/surfaces/lsfac.gif">
<p>Geometry-based solution
</section>

<section>
<h3>Erosion and deposition</h3>
<p>Net erosion and deposition computed as change in sediment transport capacity:
<br>simple to compute in GIS, combined with parameters for landcover and soils
<p> <img height="350" src="img/surfaces/p5ed_f.gif">
<small>Unit Stream Power Based Erosion-Deposition, Mitasova et al. 1995, Mitas and Mitasova 1998</small>
</section>

<section>
<h3>Path sampling of continuous fields</h3>
<p>  Next step: robust solution of shallow water flow equations and process-based sediment transport
<p>
    <img width="45%" src="img/surfaces/fanimwalk.gif">
     &nbsp; &nbsp;
    <img width="45%" src="img/surfaces/fanimhhcolp.gif">
<p>Solver based on duality of particles and fields works for noisy surfaces, captures ponding in depressions
</section>

<!--
<section>
<h3>Example application</h3>
<p>CC middle school? Germany field?
<p>    <img width="25%" src="img/surfaces/water01dsmall.gif">
    <img width="25%" src="img/surfaces/wrrwater01.jpg">
    <img width="25%" src="img/surfaces/wrrwaterdc.jpg">
    <img width="25%" src="img/surfaces/wrrwaterdc.jpg">
</section>
-->

<section>
<h3>Modeling surface runoff and erosion/deposition</h3>
<p>Impact of construction on erosion and deposition, limitations of stream buffer protection
<p> <img width="90%" src="img/surfaces/middleschool_scen.jpg">
</section>

<section>
<h3>High resolution water flow</h3>
 <p> Street level modeling of surface runoff: lidar-based DEM
and path sampling 
<p>
    <img height="450" src="img/surfaces/carywater_ortho_lg.jpg">
    <img height="450" src="img/surfaces/water_stormdrains_zoom.jpg">
</section>

<section>
<h3>Ultra-high resolution water flow: UAS mapping</h3>
 <p>Modeling impact of tillage and rills on surface water flow using 0.2m DEM derived by SfM based on UAS imagery 
<p>
    <img height="450" src="img/surfaces/agisoft_jan.gif">
</section>

<section>
<h3>Updating lidar DSM using UAS based SfM</h3>
<p>2015 lidar updated with 2018 UAS data: forested are replaced by a new school
<p>
    <img height="450" src="img/surfaces/uas_lidar_update.gif">
</section>

<section>
<h2>Tangible interface for surface analysis and process modeling</h2>
</section>

<section>
<h3>Tangible Landscape</h3>
<p> Bringing people together around GIS: Tangible user interface for GRASS GIS
<p>Designed to make working with geospatial data and simulations engaging, and fun</p>
<p>
    <img height="180" src="img/surfaces/tangible_landscape_compcrop.jpg">
<p>
Petrasova, A. et al. (2018). Tangible Modeling with Open Source GIS. Second edition. Springer International Publishing.
<a href="https://doi.org/10.1007/978-3-319-89303-7">https://doi.org/10.1007/978-3-319-89303-7</a>
</section>

<section>
<h3>How does it work?</h3>
<iframe data-autoplay width="50%" height="330" src="https://www.youtube.com/embed/Cd3cCQTGer4?rel=0&amp;showinfo=0&amp;loop=1&amp;playlist=Cd3cCQTGer4" frameborder="0" allowfullscreen></iframe>
&nbsp; &nbsp;<img height=380 src="img/surfaces/rendered_diagram_2.png">
<p>Tangible Landscape couples a digital and a physical model through a continuous cycle of 3D scanning, geospatial modeling, and projection</p>
</section>

<section>
<h3>Interactions</h3>
<p><img height="450" src="img/surfaces/tl_interactions_all.jpg">
</section>

<section>
    <h3>Coupling with 3D rendering</h3>
<p><img height="450" src="img/surfaces/process4.png">
</section>

<section>
    <h3>Design scenario analysis</h3>
<p><img height="480" src="img/surfaces/process7.png">
</section>

<!--
<section>
    <h3>Tangible Landscape + Immersive Virtual Reality</h3>
<img height="180" src="img/surfaces/coupling_case3.jpg">
  <iframe data-autoplay width="853" height="480"  src="https://www.youtube.com/embed/pYbpEMjME1Y?rel=0&amp;showinfo=0" frameborder="0" allo
wfullscreen></iframe>
<iframe width="560" height="315" src="https://www.youtube.com/embed/akCTeknStmQ?rel=0&amp;start=32" frameborder="0" allow="autoplay; encrypted-me
dia" allowfullscreen></iframe>
</section>
-->

<section>
<h3>Tangible Landscape for designers and researchers</h3>
<p>
<img height="300px" src="img/surfaces/tl_planting_3.jpg">
<img height="300px" src="img/surfaces/TL_scientists.jpg">
</section>

<section>
<h3>Tangible Landscape for education</h3>
<p>
<iframe width="560" height="315" src="https://www.youtube.com/embed/jX6FurEeW28?rel=0" frameborder="0" allow="autoplay; encrypted-media" allowfullscreen></iframe>
<img height="260" src="img/surfaces/collaboration2.JPG">
</section>

<section>
<h3>Tangible Landscape for communities</h3>
Platform for decision-making and science communication
    where people of different backgrounds can interact.
<p>
<img height="220px" src="img/surfaces/bhigames_composite.jpg">
<br>Tangible Landscape website: 
<a href="tangible-landscape.github.io">tangible-landscape.github.io</a>
<br>TL wiki: github.com/tangible-landscape/grass-tangible-landscape/wiki
</section>

<section>
<h2>Students are making an impact</h2>
 <p> Integration of open source GIS in courses
 <p> Project-based graduate courses since 2008 
</section>

<section>
<h3>Onset of bridge flooding</h3>
<p><small>William Ross for NC disaster management</small>
<p><img height="120" src="img/surfaces/bridges_ortho.jpg">
<img height="120" src="img/surfaces/bridges_dry.jpg">
<img height="120" src="img/surfaces/bridges_10yr.jpg">
<img height="120" src="img/surfaces/bridges_500yr.jpg">
<img height="130" src="img/surfaces/floodedI40_swinefac.jpg">
</p>
<small> <a href="https://www.youtube.com/watch?v=jTXa4sIxQvI">I-40 as a river in NCDOT drone video</a></small>
</section>

<section>
<h3>County map of flooded bridges</h3>
<p><small>William Ross for NC disaster management</small>
<p>Flooded bridges mapped based on lidar, bridge and inundation data for 100 yr storm
<br><img height="400" src="img/surfaces/bridgesall.jpg">
<img height="420" src="img/surfaces/bridgesall100yr.jpg">
</section>

<!--
<section>
<h3>Drones for floodwater depth</h3>
<p>William Ross for NC disaster management
</p>
</section>

<section>
<h3>Coastal flooding</h3>
High resolution modeling is important
<p><img height="300" src="img/surfaces/anim_storsurge.gif">
<img height="300" src="img/surfaces/ncdot_cc_mirlo2012camp.jpg">
</section>
-->

<section>
<h3>Improving storm surge flooding predictions</h3>
<p>Nelson Tull for operational storm surge prediction using ADCIRC
<br> Hurricane Matthew Hindcast - number of buildings flooded: before enhancement: 2435; 
after: 3886, a 60 percent increase.
<p><img height="350" src="img/surfaces/stormsurge_refined.png">
</p>
<p class="credit">N. Tull, J.C. Dietrich, T.E. Langan, H. Mitasova, B.O. Blanton, J.G. Fleming, R.A. Luettich
2018, Improving Accuracy of Real-Time Storm Surge Inundation Predictions Using GRASS GIS, Poster at ASBPA conference,
October 2017. (American Shore and Beach Preservation Association)
</p>
</section>

<section>
<h2>Beyond bare earth surface</h2>
</section>

<section>
<h3>Individual tree detection from lidar</h3>
Geomorphons (Jasiewicz, Stepinski 2013) applied to vegetation surface: 
peaks represent individual trees. Detected trees are replaced by modeled trunks 
to improve accuracy of viewscape analysis (Tabrizian et al. 2018)
<br>
<img height="260" src="img/surfaces/geomorphon.png">
<img height="260" src="img/surfaces/trunk_replace.jpg">
<!--
<br> <small>row crop growth analysis</small>
<br>
<img height="170" src="img/surfaces/geomorph_cropsurface_zoom.jpg">
-->
</section>

<section>
<h3>Beyond bare earth surface: vegetation voxel models</h3>
Generalized Fragmentation Index derived from 3D grid point counts: 
vertical slice of raw point cloud and slice of fragmentation index 3D raster
<p>
<img height="350" src="img/surfaces/profiles_points_and_ff.png">
<!--<img height="200" src="img/surfaces/profile3d.png">-->
</section>

<section>
<h3>Beyond bare earth surface: vegetation voxel models</h3>
Slicing through fragmentation index 3D raster
<p>
<img height="400" src="img/surfaces/voxels_vegetation_anim.gif">
<small>Petras, V., D. J. Newcomb, and H. Mitasova. 2017. Generalized 3D fragmentation index derived from lidar point clouds. In: Open Geospatial Data, Software and Standards 2(9). DOI 10.1186/s40965-017-0021-8 </small>
</section>

<section>
<h3>Beyond bare earth surface: urban topography</h3>
Solar irradiation during summer solstice at NCSU Centennial Campus
<p>
<img height="430" src="img/surfaces/summer_solstice_centennial.gif">
</section>


<section>
<h3>Mapping pedestrian density from webcams</h3>
Georeferencing location of pedestrians from public webcams 
<p>
<img height="300" src="img/webcam_georeferencing.jpg"></img>
<p>
<small>Petrasova A., Hipp J. A., Mitasova H., Visualization and analysis of active transportation patterns derived from public webcams. FOSS4G 2017 - Boston, August 2017.</small>
</section>

<section>
<h3>Space-time cube visualization of pedestrian density</h3>
Time series of predestrian locations is transformed into
continuous space-time model using kernel density function
<p>
<img height="300" src="img/surfaces/STC_density.png"></img>
<img height="300" src="img/surfaces/GRASS_rendering.png"></img>
<p>Selected density value visualized as isosurface in space-time cube
</section>

<section data-camera="3760_2014_2012_people" data-slidenum="12,14">
<h3>Change in pedestrian density (2014 minus 2012)</h3>
     <p style="font-size: 90%">Positive values ~ increase in density in 2014,
               Negative values ~ decrease in density in 2014</p>
    <aside class="notes">
    Since the Kernel Density is a continuous field, we can easily
    subtract the density before and after and get a difference in pedestrian
    density, where the positive values mean increase in density after the reconstruction.
    </aside>
</section>


<section>
<h3>Open Science</h3>
<p>Developing open source software and contributing to OSGeo projects:
<p>GRASS GIS <a href="https://grass.osgeo.org/">https://grass.osgeo.org/</a>
<br>Tangible Landscape  <a href="https://tangible-landscape.github.io">tangible-landscape.github.io</a>
<p>Open access educational material:
<p>NCSU GeoForAll Lab Courses and Workshops
<a href="https://geospatial.ncsu.edu/geoforall/courses.html">https://geospatial.ncsu.edu/geoforall/courses.html</a>
<p><img height="280" src="img/surfaces/geovizlab_people2018.jpg">
</section>

<section>
<h3>Thank You!</h3>
<p>Thank you all for your contributions to the field - data, methods, algorithms and tools,
that helped to bring the discipline to its current thriving state </p>
<p>
<iframe data-autoplay width="700" height="350" src="https://www.youtube.com/embed/Uje8ORyhBaQ?rel=0&amp;showinfo=0&amp;loop=1&amp;playlist=Uje8ORyhBaQ" frameborder="0" allowfullscreen></iframe>
</section>

<section>
    <h3>Appendix</h3>
Links to related talks:
TL webinar, GRASS7, Lidar, ICC talk etc.
</section>

<!-- 
<section>
    <h3>Visualization: Blend4Web</h3>
<iframe class="stretch" src="./blend4web.html?autorotate"></iframe>
</section>

for I in `ls *9706*`
do
scp $I akratoc@fatra.cnr.ncsu.edu:/var/www/html/cJw9c0/nJ0qKyeeuAXuWFouqfJx0GRMVU7OZhcPfNzy9/amos/rendering/
done

for I in `ls *10823*`
do
scp $I akratoc@fatra.cnr.ncsu.edu:/var/www/html/cJw9c0/nJ0qKyeeuAXuWFouqfJx0GRMVU7OZhcPfNzy9/amos/rendering/
done
-->



<!-- This is a generated file. Do not edit. -->
        </div>  <!-- slides -->

    </div>  <!-- reveal -->
    <!--
        Home button or link to a parent page
        If you want this to be unique for every page (slide deck),
        then remove it from here and put it at the end of each
        file (or series of files) creating one page
        (the position will be little different)
        TODO: some JS is needed to move it to the right position
    -->
    <div class="parent-page">
        <!-- alternative symbol: &#x1f3e0; -->
        <a href="https://github.com/petrasovaa/amos-STC-presentation" title="Go to the repository">
        <img width="15px" src="img/home.svg"></a>
    </div>

        <script src="lib/js/head.min.js"></script>
        <script src="js/reveal.js"></script>

        <script>

            // Full list of configuration options available here:
            // https://github.com/hakimel/reveal.js#configuration
            Reveal.initialize({
                // Display controls in the bottom right corner
                controls: false,

                // Display a presentation progress bar
                progress: true,
                
                center: true,
                showNotes: false,
                // Display the page number of the current slide
                slideNumber: false,

                // Enable the slide overview mode
                overview: true,

                // Turns fragments on and off globally
                fragments: true,

                // The "normal" size of the presentation, aspect ratio will be preserved
                // when the presentation is scaled to fit different resolutions. Can be
                // specified using percentage units.
                // width: 960,
                // height: 700,
                
                // Factor of the display size that should remain empty around the content
                margin: 0.05,  // increase?

                // Bounds for smallest/largest possible scale to apply to content
                minScale: 0.5,
                maxScale: 5.0,

                theme: Reveal.getQueryHash().theme,  // available themes are in /css/theme
                transition: Reveal.getQueryHash().transition || 'none', // default/cube/page/concave/zoom/linear/fade/none

                // Push each slide change to the browser history
                history: true,
                // Enable keyboard shortcuts for navigation
                keyboard: true,

                // Vertical centering of slides
                center: true,

                // Enables touch navigation on devices with touch input
                touch: true,

                // Loop the presentation
                loop: false,
                // Flags if the presentation is running in an embedded mode,
                // i.e. contained within a limited portion of the screen
                embedded: false,

                // Number of milliseconds between automatically proceeding to the
                // next slide, disabled when set to 0, this value can be overwritten
                // by using a data-autoslide attribute on your slides
                autoSlide: 0,

                // Stop auto-sliding after user input
                autoSlideStoppable: true,

                // Enable slide navigation via mouse wheel
                mouseWheel: false,

                // Hides the address bar on mobile devices
                hideAddressBar: true,

                // Opens links in an iframe preview overlay
                previewLinks: false,

                // Transition speed
                transitionSpeed: 'default', // default/fast/slow

                // Transition style for full page slide backgrounds
                backgroundTransition: 'none', // default/none/slide/concave/convex/zoom

                // Number of slides away from the current that are visible
                viewDistance: 3,

                // Parallax background image
                //parallaxBackgroundImage: '', // e.g. "'https://s3.amazonaws.com/hakim-static/reveal-js/reveal-parallax-1.jpg'"

                // Parallax background size
                //parallaxBackgroundSize: '' // CSS syntax, e.g. "2100px 900px"
                // Optional libraries used to extend on reveal.js
                dependencies: [
                    { src: 'lib/js/classList.js', condition: function() { return !document.body.classList; } },
                    { src: 'plugin/markdown/marked.js', condition: function() { return !!document.querySelector( '[data-markdown]' ); } },
                    { src: 'plugin/markdown/markdown.js', condition: function() { return !!document.querySelector( '[data-markdown]' ); } },
                    { src: 'plugin/highlight/highlight.js', async: true, callback: function() { hljs.initHighlightingOnLoad(); } },
                    { src: 'plugin/zoom-js/zoom.js', async: true, condition: function() { return !!document.body.classList; } },
                    { src: 'plugin/notes/notes.js', async: true, condition: function() { return !!document.body.classList; } },
                    { src: 'plugin/math/math.js', async: true }
                ]
            });

        </script>
<script src="js/nouislider.min.js"></script>
<script src="js/jquery-2.2.4.min.js"></script>
<script>
Reveal.addEventListener( 'ready', function( event ) {
	var nSlides = Reveal.getTotalSlides();

    for (i = 0; i < nSlides; i++) {
        createSlidersWebcam(Reveal.getSlide(i))
        createSlidersAnim(Reveal.getSlide(i))
    }
    
} );

function createSlidersWebcam(slide) {
    if (!$(slide).attr('data-camera')) {
        return;
    }
    var cam_number = $(slide).data('camera').split("_")[0]
    var slidenum = $(slide).data('slidenum')
    var slidenums = slidenum.split(",")
    slhtml = `<div  style="float:left; max-width:80%">
    <img id="animimage" width="100%" style="margin:auto"></div>
    <div style="float:right; max-width:20%">
    <img src="img/legend.png" width="200px">`
    if (slidenums[0] != -1) {
        slhtml += `<div style="font-size:70%">Isosurface <span style="font-size:50%">(people per 100 m<sup><span style="font-size:70%">2</span></sup>h)</span></div>
                   <div class="slider" id="slider1" style="background: #d2d2d2;width: 200px;margin: auto;margin-bottom: 15px"></div>`
    }
    if (slidenums[1] != -1) {
        slhtml += `<div style="font-size:70%">Rotate</div>
                   <div class="slider" id="slider2" style="background: #d2d2d2;width: 200px;margin: auto;margin-bottom: 15px"></div>`
    }
    slhtml += '</div>'
    slide.innerHTML += slhtml
    if (slidenums[0] != -1) {
        var slider1 = slide.querySelector('#slider1');
        noUiSlider.create(slider1, {
        	start: [12],
            step: 1,
        	connect: true,
        	range: {
        		'min': 0,
        		'max': 19
        	}
        });
        slider1.noUiSlider.on('slide', setImage);
        slider1.noUiSlider.set(slidenums[0])
    }
    if (slidenums[1] != -1) {
        var slider2 = slide.querySelector('#slider2');
        noUiSlider.create(slider2, {
            start: [0],
            step: 1,
            connect: true,
            range: {
                'min': 0,
                'max': 19
            }
        });
        slider2.noUiSlider.on('slide', setImage);
        slider2.noUiSlider.set(slidenums[1])
    }
    var animimage = slide.querySelector('#animimage')


    setImage()
    
    function setImage(){
        var value1 = 0
        var value2 = 0
        if (slidenums[0] != -1) {
            value1 = parseInt(slider1.noUiSlider.get());
        }
        if (slidenums[1] != -1) {
            value2 = parseInt(slider2.noUiSlider.get());
        }
        //var path = "/media/anna/Data/Projects/webcams/renderings/"
        var path = "http://fatra.cnr.ncsu.edu/cJw9c0/nJ0qKyeeuAXuWFouqfJx0GRMVU7OZhcPfNzy9/amos/rendering/"
        var camera = $(slide).data('camera')
        $("#animimage", slide).attr("src", path + "map_points_points_" + camera + "." + pad(value1, 4) + "." + pad(value2, 4) +".jpg");
    }
    function pad(n, width) {
        z = '0';
        n = n + '';
        return n.length >= width ? n : new Array(width - n.length + 1).join(z) + n;
    }
}

function createSlidersAnim(slide) {

    if (!$(slide).attr('data-animate')) {
        return;
    }
    var slidenum = $(slide).data('animate')
    var slidenums = slidenum.split(",")
    slhtml = `<div class="slider" id="slider" style="background: #d2d2d2;width: 400px;margin: auto;margin-bottom: 15px"></div>`
    slhtml += `<img id="animimage" width="100%" style="margin:auto">`

    slide.innerHTML += slhtml
        var slider = slide.querySelector('#slider');
        noUiSlider.create(slider, {
            start: [0],
            step: 1,
            connect: true,
            range: {
                'min': parseInt(slidenums[0]),
                'max': parseInt(slidenums[1])
            }
        });
        slider.noUiSlider.on('slide', setImage);
        slider.noUiSlider.set(0)
    var animimage = slide.querySelector('#animimage')

    setImage()

    function setImage(){
        var value = 0
        value = parseInt(slider.noUiSlider.get());

        var path = $(slide).data('path')
        $("#animimage", slide).attr("src", path + "_" + value + ".png");
    }
}
</script>
    </body>
</html>