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ONGOING MMI RESEARCH PROJECTS
ONGOING MMI RESEARCH PROJECTS
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Collective Sensing as an Enabler for Cyber-resilient Connected Mobility

Sanjay Sarma

Dajiang Suo

  1. How can infrastructure-assisted collective sensing V2X systems enhance both safety and traffic efficiency?

  2. How can cyber threats to infrastructure sensors be mitigated in connected vehicle deployment?

  3. What is the optimal allocation of sensors to balance resolution, latency and cost? 

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Safety as a Performance Metric in Autonomous Mobility

Cathy Wu

Ao Qu

  1. What is the trade-off between safety and system performance for human-driven vehicles? How would this differ for autonomous vehicles?

  2. To what extent can large-scale traffic reconstruction contribute to the question ”how safe is safe enough” for autonomous vehicles? 

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EV Charging Infrastructure Reliability in the United States

David Keith

Jim Womack

  1. Why is the reliability of US public charging infrastructure so poor?

  2. What could be done to improve the situation?

  3. Published Research Brief - Click Here

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Replacing Declining Gas Tax Revenue
with EV Adoption

Jim Aloisi

Jinhua Zhao

Bhuvan Atluri

Yunhan Zheng

Seamus Joyce-Johnson

  1. What will be the impact of rising EV adoption on gas tax revenue?

  2. How fast will it fall under various scenarios?

  3. What are the alternatives to replace lost revenue and how effective, efficient and easily implementable are they?

  4. Read the report here.

Night Train

Transit Research Consortium

Jim Aloisi

Bhuvan Atluri

Jinhua Zhao

Anson Stewart

Haris Koutspoulis

  1. What are the implications of changes in work commuting patterns for transit ridership return, growth and financial stability?

  2. Facilitate the exchange of best practices across large public transit agencies.

  3. Conduct cross-disciplinary research into the strategic, policy, planning & operational problems of an integrated transportation system centered around transit.

  4. Members - New York, Chicago, San Francisco, Seattle, Los Angeles, Washington DC and Boston.

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Autonomous Mobility Computing Energy Consumption

Sertac Karaman

Vivienne Sze

  1. How much energy would be required to power the compute of autonomous vehicles in the future?

  2. How fast is the efficiency of computing increasing, versus the computing requirements for AVs?

  3. What is the optimal distribution of AV computing among vehicle, edge, and cloud?

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Electric Vehicle Charging Urban Optimization

Alex Jacquillat

Dan Freund

  1. Where to locate public electric vehicle chargers in an urban setting?

  2. How many and what type (power) of chargers should be used in which locations?

  3. How to optimize charging infrastructure for access, utilization, equity, etc.?

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Enabling Equitable Access to AAM Service

Hamsa Balakrishnan

  1. How do we ensure that certain communities are not disproportionately impacted by the adverse effects of Advanced Aerial Mobility (AAM) operations and also ensure equitable access to the benefits of AAM services? 

  2. How do we ensure equitable airspace access to a range of users (fleet operators) who might vary in scale of operations, business models, and missions?

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Carbon Footprint of Commuting vs WFH vs WF3P  (3rd Place)

Bhuvan Atluri

Tulio Silvera-Santos

  1. What are the current trends in work location (both day of week and longer term) in the US?

  2. What is the CO2 impact of working from home versus working at the office?

  3. What are possible levers or policies to minimize growth in CO2 emissions driven by work location options?

  4. Read Nick Caros' PhD dissertation on preparing urban mobility for the future of work here.

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Road Data Convergence: Platform Efficiencies

Jinhua Zhao

  1. How could the multiple stakeholders in road usage (such as governments maintaining the roads, businesses managing congestion on the roads via tolls, automotive insurance companies, EV charging providers) be incentivized to collaborate on the collection of road usage data?

  2. Can one coherent pricing framework be developed that addresses all externalities (e.g., safety, emissions, congestion) in a rational and effective way?

Researchers at MIT are at the forefront of today's profound changes in mobility and transportation. From helping cities shape sustainable travel behavior to harnessing artificial intelligence to improving network performance to designing automated and electric vehicles, MIT researchers are pushing the boundaries of technology and system development and leading analytical and computational innovation--while simultaneously driving emerging conversations about changing objectives and institutions. Explore more via the themes below that exhibit the wide-ranging research underway at the Institute. 
 

Systems & Operations

Public Transport

Freight and Logistics

Air Transportation

Networks and Systems

Emerging Mobility

Vehicles and Energy

Analytics & Computation

Operations Research and Statistics

Automation, Control and Artificial Intelligence

Behavior and Demand Modeling

Big Data, Visualization and Media

Planning, Policy & Institutions

Sustainability and Environment

Urban Planning, Design and Policy

Economics and Finance

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