Using Twitter to study people's crisis responses
Using Twitter to study people's crisis responses
"Sometimes there is a disconnect between what decision makers anticipate helping a community, maybe through economic forecasts, and how individuals respond to a crisis. We need to know what people think about an event to make a community more resilient during these situations," said Benjamin Rachunok, a PhD candidate in Purdue University’s School of Industrial Engineering.
Typically, social scientists gauge individual response to a disaster or crisis through surveys. But for over 60 million Americans each month, much of this conversation takes place naturally on Twitter.
Rachunok and a team of researchers at Purdue developed an algorithm that captures individuals' responses to a particular crisis via their tweets, creating what he calls a "fingerprint" that researchers and policymakers could use to better quantify what the community thinks about that crisis.
"The algorithm would be a useful tool for informing long-term recovery from a disaster and knowing where to prioritize investment or attention," said Roshi Nateghi, co-author on the work, a Purdue assistant professor of industrial engineering and environmental and ecological engineering, and head of Purdue's Laboratory for Advancing Sustainable Critical Infrastructure (LASCI).
The work, published in the journal IEEE Access, shows that these fingerprints could characterize what makes a community resilient for a range of events, such as public violence, natural disasters and even political crises such as Brexit.
"By understanding how people communicate within the confines of a community, we can start to understand the emergent properties which contribute to a community's resilience," says Jackson Bennett, co-author on the work and a Purdue master's student in industrial engineering.
The technique looks at individuals' tweets associated with an event and breaks them down into categories of community resilience, as defined by the researchers: Ecological, economical, institutional, social, infrastructure and quality of life. The algorithm automatically calculates and generates a heat map of the fingerprint, which is the specific combination of categories that make up individuals' responses to an event.
The heat map makes it easier to see which aspects of community resilience are most evident in people's reactions to certain crises, as well as how they relate to each other. The researchers found, for example, that similar events have similar fingerprints, even if they happened in different communities, such as Hurricane Harvey and Hurricane Irma or the Las Vegas shooting and Charlottesville riots.
The researchers plan to expand the algorithm's capabilities to work in real time, examine retweets and detect topics on its own rather than just relying on certain categories of community resilience. Code for the algorithm will also be made publicly available.
This work was supported by a Purdue Libraries Open Access grant and the National Science Foundation's Humans, Disasters and the Built Environment program (grant 1826161).
The research aligns with Purdue's Giant Leaps celebration, acknowledging the university's global advancements made in artificial intelligence, algorithms and automation as part of Purdue's 150th anniversary. This is one of the four themes of the yearlong celebration’s Ideas Festival, designed to showcase Purdue as an intellectual center solving real-world issues.
Writer: Kayla Wiles, 765-494-2432, firstname.lastname@example.org
Note to Journalists: The paper is online open-access at https://ieeexplore.ieee.org/document/8706991.
Understanding the resilience of a community facing a crisis event is critical to improving its adaptive capacity. Community resilience has been conceptualized as a function of the resilience of components of a community such as ecological, infrastructure, economic, and social systems, etc. In this paper, we introduce the concept of a "resilience fingerprint" and propose a multi-dimensional method for analyzing components of community resilience by leveraging existing definitions of community resilience with data from the social network Twitter. Twitter data from 14 events are analyzed and their resulting resilience fingerprints computed. We compare the fingerprints between events and show that major disasters such as hurricanes and earthquakes have a unique resilience fingerprint which is consistent between different events of the same type. Specifically, hurricanes have a distinct fingerprint which differentiates them from other major events. We analyze the components underlying the similarity among hurricanes and find that ecological, infrastructure and economic components of community resilience are the primary drivers of the difference between the community resilience of hurricanes and other major events.