The Quantified Community and Neighborhood Labs

A Framework for Computational Urban Science and Civic Technology Innovation

Research output: Contribution to journalArticle

Abstract

Instrumentation of the urban environment is not by itself sufficient to have a meaningful impact on the quality, sustainability, and resilience of cities – or more broadly on urban policy and planning. Understanding the social, economic, and cultural dynamics of urban life requires both an appreciation of the social sciences and a substantive engagement with communities across neighborhoods. The “Smart City” messaging is replete with claims of the potential for sensors and information and communication technologies (ICT) to re-shape urban life, although such rhetoric ignores the practical realities and constraints of urban decision-making and the social and distributional concerns of policy outcomes. Rather, significant progress could be achieved at the neighborhood scale by focusing diverse, intensive, and persistent real-time data collection and analysis on a “Quantified Community” (QC). The QC—a long-term neighborhood informatics research initiative—is a network of instrumented urban neighborhoods that collect, measure, and analyze data on physical and environmental conditions and human behavior to provide a rich resource to better understand how neighborhoods and the built environment affect individual and social well-being. The resulting unique experimental environment provides a testing ground for new physical and informatics technologies, policies, and behavioral interventions, allowing for unprecedented studies in urban planning and design, urban systems engineering and management, and the social sciences. Focusing on the neighborhood scale also allows for meaningful interaction with, and participation by, the people who live, work, and play in that space and shifts the emphasis of data-driven design away from top-down routinization to a human-centric problem-solving. This paper presents the conceptual framework and justification for the QC, built on the lessons learned from three initial deployments in New York City, and a networked experimental environment of neighborhood labs.

Original languageEnglish (US)
Pages (from-to)1-18
Number of pages18
JournalJournal of Urban Technology
DOIs
StateAccepted/In press - Oct 27 2016

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science and technology
innovation
science
community
informatics
urban planning
social science
technology policy
systems engineering
human behavior
information and communication technology
urban policy
urban design
urban system
conceptual framework
social economics
resilience
instrumentation
environmental factors
communication technology

Keywords

  • Big Data
  • Civic Technology
  • Computational Planning and Design
  • Neighborhood Planning
  • Urban Systems and Sensing

ASJC Scopus subject areas

  • Urban Studies

Cite this

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abstract = "Instrumentation of the urban environment is not by itself sufficient to have a meaningful impact on the quality, sustainability, and resilience of cities – or more broadly on urban policy and planning. Understanding the social, economic, and cultural dynamics of urban life requires both an appreciation of the social sciences and a substantive engagement with communities across neighborhoods. The “Smart City” messaging is replete with claims of the potential for sensors and information and communication technologies (ICT) to re-shape urban life, although such rhetoric ignores the practical realities and constraints of urban decision-making and the social and distributional concerns of policy outcomes. Rather, significant progress could be achieved at the neighborhood scale by focusing diverse, intensive, and persistent real-time data collection and analysis on a “Quantified Community” (QC). The QC—a long-term neighborhood informatics research initiative—is a network of instrumented urban neighborhoods that collect, measure, and analyze data on physical and environmental conditions and human behavior to provide a rich resource to better understand how neighborhoods and the built environment affect individual and social well-being. The resulting unique experimental environment provides a testing ground for new physical and informatics technologies, policies, and behavioral interventions, allowing for unprecedented studies in urban planning and design, urban systems engineering and management, and the social sciences. Focusing on the neighborhood scale also allows for meaningful interaction with, and participation by, the people who live, work, and play in that space and shifts the emphasis of data-driven design away from top-down routinization to a human-centric problem-solving. This paper presents the conceptual framework and justification for the QC, built on the lessons learned from three initial deployments in New York City, and a networked experimental environment of neighborhood labs.",
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