Research Projects
Start Date: October 2019
Funding: Seattle Flu Study
Summary:
The mission of the Seattle Flu Study (SFS) is to prototype city-scale capabilities for epidemic preparedness and response. One of the aims of this study is to understand methods to implement rapid interventions outside of clinical settings and within 48-72 hours of the onset of symptoms, to enable the immediate diagnosis, treatment, or isolation of flu-positive individuals.
The mission of the Seattle Flu Study (SFS) is to prototype city-scale capabilities for epidemic preparedness and response. One of the aims of this study is to understand methods to implement rapid interventions outside of clinical settings and within 48-72 hours of the onset of symptoms, to enable the immediate diagnosis, treatment, or isolation of flu-positive individuals.
Start Date: January 2022
Summary:
One of the disruptions brought by the COVID-19 pandemic was the reduction of in-store shopping, and the consequent increase in online shopping and home deliveries. In response, Cascade Bicycle Club started the Pedaling Relief Project (PRP) in 2020 — a nonprofit home delivery service run by volunteers using bikes to pick up food at food banks and deliver to food bank customers, among other services. The Supply Chain Transportation & Logistics Center (SCTL) and graduate Transportation Logistics students are undertaking a research study to analyze the transport and logistics system of the PRP and provide recommendations for operations improvement.
One of the disruptions brought by the COVID-19 pandemic was the reduction of in-store shopping, and the consequent increase in online shopping and home deliveries. In response, Cascade Bicycle Club started the Pedaling Relief Project (PRP) in 2020 — a nonprofit home delivery service run by volunteers using bikes to pick up food at food banks and deliver to food bank customers, among other services. The Supply Chain Transportation & Logistics Center (SCTL) and graduate Transportation Logistics students are undertaking a research study to analyze the transport and logistics system of the PRP and provide recommendations for operations improvement.
Start Date: January 2019
Funding: Marine Environmental Observation, Prediction and Response Network (MEOPAR), Province of British Columbia
Principal Investigator(s): Dr. Anne Goodchild
Other PI(s): Stephanie ChangCo-PI: Floris GoerlandtCo-PI: Ronald PelotCo-PI: David BristowCo-PI: Lina ZhouCo-PI: Cheng Lin
Summary:
This project aims to improve understanding of how coastal marine transportation systems would be disrupted in natural hazard events, how such disruption would impact coastal communities, and what strategies could effectively address this risk. Focusing on the movement of people and goods in the emergency response phase of a disaster, the study will develop new tools, information, and risk assessments to support preparedness planning by local and provincial governments and the transportation sector. The research will deliver: (1) workshops for engaging government and transport sector stakeholders; (2) a framework for assessing coastal community resilience to shipping disruption; (3) a simulation tool based on this framework; and (4) specific findings and recommendations for two case studies – a detailed analysis of catastrophic earthquake risk in British Columbia and exploratory analysis of hurricane risk in Atlantic Canada.
This project aims to improve understanding of how coastal marine transportation systems would be disrupted in natural hazard events, how such disruption would impact coastal communities, and what strategies could effectively address this risk. Focusing on the movement of people and goods in the emergency response phase of a disaster, the study will develop new tools, information, and risk assessments to support preparedness planning by local and provincial governments and the transportation sector. The research will deliver: (1) workshops for engaging government and transport sector stakeholders; (2) a framework for assessing coastal community resilience to shipping disruption; (3) a simulation tool based on this framework; and (4) specific findings and recommendations for two case studies – a detailed analysis of catastrophic earthquake risk in British Columbia and exploratory analysis of hurricane risk in Atlantic Canada.
Start Date: January 2019
Funding: Marine Environmental Observation, Prediction and Response Network (MEOPAR)
Principal Investigator(s): Dr. Anne Goodchild
Other PI(s): PI: Stephanie Chang (University of British Columbia)Co-PI: David Bristow (University of Victoria)Co-PI: Floris Goerlandt (Dalhousie University)Co-PI: Ron Pelot (Dalhousie University)Co-PI: Cheng Lin (University of Victoria)Co-PI: Linda Zhou (University of Victoria)
Summary:
A catastrophic earthquake could disrupt marine transportation across coastal British Columbia, severely affecting supply chains to coastal communities and emergency response capabilities. This project seeks to better understand such risks and develop effective resilience strategies for different types of coastal communities. It inquires into how disaster events would likely affect ports, marine transportation routes, and the associated movement of people and resources in the emergency response phase, and what strategies would be effective to alleviate potential consequences.
A catastrophic earthquake could disrupt marine transportation across coastal British Columbia, severely affecting supply chains to coastal communities and emergency response capabilities. This project seeks to better understand such risks and develop effective resilience strategies for different types of coastal communities. It inquires into how disaster events would likely affect ports, marine transportation routes, and the associated movement of people and resources in the emergency response phase, and what strategies would be effective to alleviate potential consequences.
Start Date: September 2017
Funding: City of Seattle Department of Transportation (SDOT), Pacific Northwest Transportation Consortium (PacTrans)
Principal Investigator(s): Dr. Anne Goodchild
Summary:
The UFL engaged multiple partners and funding sources to successfully pilot test a common carrier locker system (open to all retail and multiple delivery firms) in the 62-floor Seattle Municipal Tower skyscraper. The study tested the ability of these new mini-distribution centers to create delivery density and reduce the time delivery people have to spend in urban towers to complete the work. The Lab collected “before” and “after” data to evaluate the pilot's premise: that when delivery trucks can pull into a load/unload space that's close to a mini-distribution node with delivery density (lots of deliveries in one place), everyone benefits. UFL members UPS and the U.S. Postal Service participated in this pilot, so any package they delivered to the building went into the locker system. The pilot was open to the first 100 Municipal Tower tenants who signed up to use the lockers from March to April 2018.
The UFL engaged multiple partners and funding sources to successfully pilot test a common carrier locker system (open to all retail and multiple delivery firms) in the 62-floor Seattle Municipal Tower skyscraper. The study tested the ability of these new mini-distribution centers to create delivery density and reduce the time delivery people have to spend in urban towers to complete the work. The Lab collected “before” and “after” data to evaluate the pilot's premise: that when delivery trucks can pull into a load/unload space that's close to a mini-distribution node with delivery density (lots of deliveries in one place), everyone benefits. UFL members UPS and the U.S. Postal Service participated in this pilot, so any package they delivered to the building went into the locker system. The pilot was open to the first 100 Municipal Tower tenants who signed up to use the lockers from March to April 2018.
Start Date: July 2017
Funding: Resource Systems Group, Federal Highway Administration (FHWA)
Summary:
This project develops a national freight forecasting model for the FHWA. The model, the first of its kind at the national level, supports national freight policy making and planning. Urban Freight Lab researchers will identify the most useful and promising structures for a national model and are leading the evaluation of model components and their integration, and developing an approach to test the potential specifications for each model component and are contributing to the development of national sources of data for use in the model. The project will demonstrate the model in a software application.
This project develops a national freight forecasting model for the FHWA. The model, the first of its kind at the national level, supports national freight policy making and planning. Urban Freight Lab researchers will identify the most useful and promising structures for a national model and are leading the evaluation of model components and their integration, and developing an approach to test the potential specifications for each model component and are contributing to the development of national sources of data for use in the model. The project will demonstrate the model in a software application.