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Updated poster template

master
Micah Halter 1 year ago
parent
commit
3e4c256791
  1. 12
      conference-poster/poster.html
  2. BIN
      conference-poster/poster.pdf
  3. 4
      conference-poster/poster.rmd

12
conference-poster/poster.html

@ -15,6 +15,7 @@
<!--
Font-awesome icons ie github or twitter
-->
@ -124,7 +125,7 @@ padding: 0px;
}
.outer {
width: 36in;
height: calc(48in * (1 - 0.2 - 0.1 - 0.01) );
height: calc(48in * (1 - 0.15 - 0.1 - 0.01) );
-webkit-column-count: 3; /* Chrome, Safari, Opera */
-moz-column-count: 3; /* Firefox */
column-count: 3;
@ -145,7 +146,7 @@ column-rule-style: none;
column-rule-color: black;
background-color: #ffffff;
font-family: Rasa;
margin-top: calc(48in * 0.2 );
margin-top: calc(48in * 0.15 );
padding-top: 1em;
padding-bottom: 1em;
}
@ -238,7 +239,7 @@ text-align: left;
}
.main {
width: 36in;
height: calc(48in * 0.2);
height: calc(48in * 0.15);
position: absolute;
background-color: #101B49;
color: #ffffff90;
@ -415,6 +416,7 @@ span > #tab:mytable {
These wiring diagrams allow us to perform model augmentation and fusion at the semantic level, and the fusion of the differential equations is handled automatically.
We then augmented the Lotka-Volterra model from Figure <a href="#fig:volterra">2</a> to model mutual predation and composed it with the Ross Malaria model from Figure <a href="#fig:ross">3</a> to get a model that simulates both, shown in Figure <a href="#fig:volterraross">4</a>.
Finally we generated the code to simulate the new model, and the results are shown in Figures <a href="#fig:results">5</a> and <a href="#fig:resultszoom">6</a>.</p>
<p><br /></p>
<div class="figure" style="text-align: center"><span id="fig:volterradiffeq"></span>
<img src="figs/volterra-diffeq.png" alt="The full set of differential equations of the Lotka-Volterra model that we want to represent as a mathematical structure grounded in semantic knowledge." width="80%" />
<p class="caption">
@ -469,9 +471,9 @@ Figure 6: Zooming into the beginning of the graph in Figure <a href="#fig:result
<h1>Acknowledgments</h1>
<p>This material is based upon work supported by the Defense Advanced Research Projects Agency (DARPA) under Agreement No. HR00111990008.</p>
</div>
<div id="references" class="section level1 unnumbered">
<div id="references" class="section level1">
<h1>References</h1>
<div id="refs" class="references">
<div id="refs" class="references hanging-indent">
<div id="ref-fong">
<p>Fong, Brendan. 2018. “Seven Sketches in Compositionality: An Invitation to Applied Category Theory.”</p>
</div>

BIN
conference-poster/poster.pdf

4
conference-poster/poster.rmd

@ -1,5 +1,5 @@
---
main_topsize: 0.2 #percent coverage of the poster
main_topsize: 0.15 #percent coverage of the poster
main_bottomsize: 0.1
column_numbers: 3
#ESSENTIALS
@ -81,6 +81,8 @@ These wiring diagrams allow us to perform model augmentation and fusion at the s
We then augmented the Lotka-Volterra model from Figure \@ref(fig:volterra) to model mutual predation and composed it with the Ross Malaria model from Figure \@ref(fig:ross) to get a model that simulates both, shown in Figure \@ref(fig:volterraross).
Finally we generated the code to simulate the new model, and the results are shown in Figures \@ref(fig:results) and \@ref(fig:resultszoom).
<br />
```{r, volterradiffeq, fig.cap='The full set of differential equations of the Lotka-Volterra model that we want to represent as a mathematical structure grounded in semantic knowledge.', out.width="80%"}
knitr::include_graphics("figs/volterra-diffeq.png")
```

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