d – Spring Show 2020 /shows/spring2020/ Mon, 14 Dec 2020 18:39:31 +0000 en-US hourly 1 https://wordpress.org/?v=6.5.5 PandemicSim /shows/spring2020/pandemicsim/ /shows/spring2020/pandemicsim/#respond Mon, 18 May 2020 03:46:41 +0000 https://itp.nyu.edu/shows/spring2020/pandemicsim/ Continue reading "PandemicSim"

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A simulation demonstrating the benefits of social distancing during a pandemic

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The right side of the image has many small circles, some green, some red and some purple. The left hand side has a graph of the same colors at the top, and a user interface at the bottom with options to change the simulation. Screenshot of PandemicSim - Main Image - The right side of the image has many small circles, some green, some red and some purple. The left hand side has a graph of the same colors at the top, and a user interface at the bottom with options to change the Screenshot of PandemicSim - Main Image - The right side of the image has many small circles, some green, some red and some purple. The left hand side has a graph of the same colors at the top, and a user interface at the bottom with options to change the Screenshot of PandemicSim - Main Image - The right side of the image has many small circles, some green, some red and some purple. The left hand side has a graph of the same colors at the top, and a user interface at the bottom with options to change the
https://youtu.be/YQt4y0cIees

Description

My project consists of 100 little balls on a screen, plus a user interface. One of those balls is “infected”, the other 99 are “healthy”. Each ball moves in a random direction but fixed velocity. An infected ball can recover after a certain number of seconds. When a healthy ball bumps into an infected one, it becomes infected. As can be expected, the “infection” spreads exponentially.

What excites me about this project is that the concept is quite simple, but it produces delightful and interesting results out of a system that is too complex to orchestrate yourself sequentially. You could never tell those 100 balls what to do every frame. Instead, you tell them how to behave, and then watch the magic happen. Maybe the “infected ball” won't touch any others, and it'll end right there when it “recovers”. Maybe they'll all become infected. Maybe half will. Most of the time, however, you'll see a logistic curve in the cumulative number of infections, mirroring what happens in real life.

The project is meant to visually demonstrate the benefits of social distancing in a post-Covid-19 world. It was inspired by an article from the Washington Post that showed a very similar model, except without the ability to change the settings of the simulation. I wanted to create something visually pleasing and modern looking that would embody the reasoning behind social distancing as a way of slowing the spread of the virus.

I added the ability to change the population size and death rate to make the simulator representative of pandemics in general. The default setting is at the estimated Covid-19 death rate of 2%. I also added an automatic peak finder that would show in the graph where the peak of the simulation outbreak occurred. This helps demonstrate the stark difference between the social distancing and business as usual models.

IM Abu Dhabi
IM-UH.1010
Introduction to Interactive Media
Art,Play/Games
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